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import numpy as np | |
import cv2 | |
class_names = [ | |
"person", | |
"bicycle", | |
"car", | |
"motorcycle", | |
"airplane", | |
"bus", | |
"train", | |
"truck", | |
"boat", | |
"traffic light", | |
"fire hydrant", | |
"stop sign", | |
"parking meter", | |
"bench", | |
"bird", | |
"cat", | |
"dog", | |
"horse", | |
"sheep", | |
"cow", | |
"elephant", | |
"bear", | |
"zebra", | |
"giraffe", | |
"backpack", | |
"umbrella", | |
"handbag", | |
"tie", | |
"suitcase", | |
"frisbee", | |
"skis", | |
"snowboard", | |
"sports ball", | |
"kite", | |
"baseball bat", | |
"baseball glove", | |
"skateboard", | |
"surfboard", | |
"tennis racket", | |
"bottle", | |
"wine glass", | |
"cup", | |
"fork", | |
"knife", | |
"spoon", | |
"bowl", | |
"banana", | |
"apple", | |
"sandwich", | |
"orange", | |
"broccoli", | |
"carrot", | |
"hot dog", | |
"pizza", | |
"donut", | |
"cake", | |
"chair", | |
"couch", | |
"potted plant", | |
"bed", | |
"dining table", | |
"toilet", | |
"tv", | |
"laptop", | |
"mouse", | |
"remote", | |
"keyboard", | |
"cell phone", | |
"microwave", | |
"oven", | |
"toaster", | |
"sink", | |
"refrigerator", | |
"book", | |
"clock", | |
"vase", | |
"scissors", | |
"teddy bear", | |
"hair drier", | |
"toothbrush", | |
] | |
# Create a list of colors for each class where each color is a tuple of 3 integer values | |
rng = np.random.default_rng(3) | |
colors = rng.uniform(0, 255, size=(len(class_names), 3)) | |
def nms(boxes, scores, iou_threshold): | |
# Sort by score | |
sorted_indices = np.argsort(scores)[::-1] | |
keep_boxes = [] | |
while sorted_indices.size > 0: | |
# Pick the last box | |
box_id = sorted_indices[0] | |
keep_boxes.append(box_id) | |
# Compute IoU of the picked box with the rest | |
ious = compute_iou(boxes[box_id, :], boxes[sorted_indices[1:], :]) | |
# Remove boxes with IoU over the threshold | |
keep_indices = np.where(ious < iou_threshold)[0] | |
# print(keep_indices.shape, sorted_indices.shape) | |
sorted_indices = sorted_indices[keep_indices + 1] | |
return keep_boxes | |
def multiclass_nms(boxes, scores, class_ids, iou_threshold): | |
unique_class_ids = np.unique(class_ids) | |
keep_boxes = [] | |
for class_id in unique_class_ids: | |
class_indices = np.where(class_ids == class_id)[0] | |
class_boxes = boxes[class_indices, :] | |
class_scores = scores[class_indices] | |
class_keep_boxes = nms(class_boxes, class_scores, iou_threshold) | |
keep_boxes.extend(class_indices[class_keep_boxes]) | |
return keep_boxes | |
def compute_iou(box, boxes): | |
# Compute xmin, ymin, xmax, ymax for both boxes | |
xmin = np.maximum(box[0], boxes[:, 0]) | |
ymin = np.maximum(box[1], boxes[:, 1]) | |
xmax = np.minimum(box[2], boxes[:, 2]) | |
ymax = np.minimum(box[3], boxes[:, 3]) | |
# Compute intersection area | |
intersection_area = np.maximum(0, xmax - xmin) * np.maximum(0, ymax - ymin) | |
# Compute union area | |
box_area = (box[2] - box[0]) * (box[3] - box[1]) | |
boxes_area = (boxes[:, 2] - boxes[:, 0]) * (boxes[:, 3] - boxes[:, 1]) | |
union_area = box_area + boxes_area - intersection_area | |
# Compute IoU | |
iou = intersection_area / union_area | |
return iou | |
def xywh2xyxy(x): | |
# Convert bounding box (x, y, w, h) to bounding box (x1, y1, x2, y2) | |
y = np.copy(x) | |
y[..., 0] = x[..., 0] - x[..., 2] / 2 | |
y[..., 1] = x[..., 1] - x[..., 3] / 2 | |
y[..., 2] = x[..., 0] + x[..., 2] / 2 | |
y[..., 3] = x[..., 1] + x[..., 3] / 2 | |
return y | |
def draw_detections(image, boxes, scores, class_ids, mask_alpha=0.3): | |
det_img = image.copy() | |
img_height, img_width = image.shape[:2] | |
font_size = min([img_height, img_width]) * 0.0006 | |
text_thickness = int(min([img_height, img_width]) * 0.001) | |
#det_img = draw_masks(det_img, boxes, class_ids, mask_alpha) | |
# Draw bounding boxes and labels of detections | |
for class_id, box, score in zip(class_ids, boxes, scores): | |
color = colors[class_id] | |
draw_box(det_img, box, color) | |
label = class_names[class_id] | |
caption = f"{label} {int(score * 100)}%" | |
draw_text(det_img, caption, box, color, font_size, text_thickness) | |
return det_img | |
def draw_box( | |
image: np.ndarray, | |
box: np.ndarray, | |
color: tuple[int, int, int] = (0, 0, 255), | |
thickness: int = 2, | |
) -> np.ndarray: | |
x1, y1, x2, y2 = box.astype(int) | |
return cv2.rectangle(image, (x1, y1), (x2, y2), color, thickness) | |
def draw_text( | |
image: np.ndarray, | |
text: str, | |
box: np.ndarray, | |
color: tuple[int, int, int] = (0, 0, 255), | |
font_size: float = 0.001, | |
text_thickness: int = 2, | |
) -> np.ndarray: | |
x1, y1, x2, y2 = box.astype(int) | |
(tw, th), _ = cv2.getTextSize( | |
text=text, | |
fontFace=cv2.FONT_HERSHEY_SIMPLEX, | |
fontScale=font_size, | |
thickness=text_thickness, | |
) | |
th = int(th * 1.2) | |
cv2.rectangle(image, (x1, y1), (x1 + tw, y1 - th), color, -1) | |
return cv2.putText( | |
image, | |
text, | |
(x1, y1), | |
cv2.FONT_HERSHEY_SIMPLEX, | |
font_size, | |
(255, 255, 255), | |
text_thickness, | |
cv2.LINE_AA, | |
) | |
def draw_masks( | |
image: np.ndarray, boxes: np.ndarray, classes: np.ndarray, mask_alpha: float = 0.3 | |
) -> np.ndarray: | |
mask_img = image.copy() | |
# Draw bounding boxes and labels of detections | |
for box, class_id in zip(boxes, classes): | |
color = colors[class_id] | |
x1, y1, x2, y2 = box.astype(int) | |
# Draw fill rectangle in mask image | |
cv2.rectangle(mask_img, (x1, y1), (x2, y2), color, -1) | |
return cv2.addWeighted(mask_img, mask_alpha, image, 1 - mask_alpha, 0) |