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from typing import List, Tuple, Dict, Optional
from ultralytics import YOLO
from numpy import ndarray
from pydantic import BaseModel
import numpy as np
import cv2
class BoundingBox(BaseModel):
x1: int
y1: int
x2: int
y2: int
cls_id: int
conf: float
class TVFrameResult(BaseModel):
frame_id: int
boxes: List[BoundingBox]
keypoints: List[Tuple[int, int]]
class Miner:
# Optimized for enumeration and placement - more aggressive detection
QUASI_TOTAL_IOA: float = 0.88 # Slightly lower to keep more detections
SMALL_CONTAINED_IOA: float = 0.82 # More lenient for small objects
SMALL_RATIO_MAX: float = 0.55 # Allow slightly larger size differences
SINGLE_PLAYER_HUE_PIVOT: float = 90.0
CORNER_INDICES = {0, 5, 24, 29}
# Enumeration-specific constants
AGGRESSIVE_SCALES = [1.0, 1.3, 0.7, 1.1, 0.9] # More scales for better coverage
ENUMERATION_NMS_THRESHOLD = 0.4 # Lower NMS for better enumeration
SMALL_OBJECT_CONF_BOOST = 1.15 # Boost confidence for small objects
def __init__(self, path_hf_repo: Path) -> None:
self.bbox_model = YOLO(path_hf_repo / "objdetect.pt")
print("BBox Model (objdetect.pt) Loaded")
self.keypoints_model = YOLO(path_hf_repo / "keypointdetect.pt")
print("Keypoints Model (keypointdetect.pt) Loaded")
def __repr__(self) -> str:
return (
f"BBox Model: {type(self.bbox_model).__name__}\n"
f"Keypoints Model: {type(self.keypoints_model).__name__}"
)
@staticmethod
def _clip_box_to_image(x1: int, y1: int, x2: int, y2: int, w: int, h: int) -> Tuple[int, int, int, int]:
x1 = max(0, min(int(x1), w - 1))
y1 = max(0, min(int(y1), h - 1))
x2 = max(0, min(int(x2), w - 1))
y2 = max(0, min(int(y2), h - 1))
if x2 <= x1:
x2 = min(w - 1, x1 + 1)
if y2 <= y1:
y2 = min(h - 1, y1 + 1)
return x1, y1, x2, y2
@staticmethod
def _area(bb: BoundingBox) -> int:
return max(0, bb.x2 - bb.x1) * max(0, bb.y2 - bb.y1)
@staticmethod
def _intersect_area(a: BoundingBox, b: BoundingBox) -> int:
ix1 = max(a.x1, b.x1)
iy1 = max(a.y1, b.y1)
ix2 = min(a.x2, b.x2)
iy2 = min(a.y2, b.y2)
if ix2 <= ix1 or iy2 <= iy1:
return 0
return (ix2 - ix1) * (iy2 - iy1)
@staticmethod
def _center(bb: BoundingBox) -> Tuple[float, float]:
return (0.5 * (bb.x1 + bb.x2), 0.5 * (bb.y1 + bb.y2))
@staticmethod
def _mean_hs(img_bgr: np.ndarray) -> Tuple[float, float]:
hsv = cv2.cvtColor(img_bgr, cv2.COLOR_BGR2HSV)
return float(np.mean(hsv[:, :, 0])), float(np.mean(hsv[:, :, 1]))
def _hs_feature_from_roi(self, img_bgr: np.ndarray, box: BoundingBox) -> np.ndarray:
H, W = img_bgr.shape[:2]
x1, y1, x2, y2 = self._clip_box_to_image(box.x1, box.y1, box.x2, box.y2, W, H)
roi = img_bgr[y1:y2, x1:x2]
if roi.size == 0:
return np.array([0.0, 0.0], dtype=np.float32)
hsv = cv2.cvtColor(roi, cv2.COLOR_BGR2HSV)
lower_green = np.array([35, 60, 60], dtype=np.uint8)
upper_green = np.array([85, 255, 255], dtype=np.uint8)
green_mask = cv2.inRange(hsv, lower_green, upper_green)
non_green_mask = cv2.bitwise_not(green_mask)
num_non_green = int(np.count_nonzero(non_green_mask))
total = hsv.shape[0] * hsv.shape[1]
if num_non_green > max(50, total // 20):
h_vals = hsv[:, :, 0][non_green_mask > 0]
s_vals = hsv[:, :, 1][non_green_mask > 0]
h_mean = float(np.mean(h_vals)) if h_vals.size else 0.0
s_mean = float(np.mean(s_vals)) if s_vals.size else 0.0
else:
h_mean, s_mean = self._mean_hs(roi)
return np.array([h_mean, s_mean], dtype=np.float32)
def _ioa(self, a: BoundingBox, b: BoundingBox) -> float:
inter = self._intersect_area(a, b)
aa = self._area(a)
if aa <= 0:
return 0.0
return inter / aa
def suppress_quasi_total_containment(self, boxes: List[BoundingBox]) -> List[BoundingBox]:
if len(boxes) <= 1:
return boxes
keep = [True] * len(boxes)
for i in range(len(boxes)):
if not keep[i]:
continue
for j in range(len(boxes)):
if i == j or not keep[j]:
continue
ioa_i_in_j = self._ioa(boxes[i], boxes[j])
if ioa_i_in_j >= self.QUASI_TOTAL_IOA:
keep[i] = False
break
return [bb for bb, k in zip(boxes, keep) if k]
def suppress_small_contained(self, boxes: List[BoundingBox]) -> List[BoundingBox]:
if len(boxes) <= 1:
return boxes
keep = [True] * len(boxes)
areas = [self._area(bb) for bb in boxes]
for i in range(len(boxes)):
if not keep[i]:
continue
for j in range(len(boxes)):
if i == j or not keep[j]:
continue
ai, aj = areas[i], areas[j]
if ai == 0 or aj == 0:
continue
if ai <= aj:
ratio = ai / aj
if ratio <= self.SMALL_RATIO_MAX:
ioa_i_in_j = self._ioa(boxes[i], boxes[j])
if ioa_i_in_j >= self.SMALL_CONTAINED_IOA:
keep[i] = False
break
else:
ratio = aj / ai
if ratio <= self.SMALL_RATIO_MAX:
ioa_j_in_i = self._ioa(boxes[j], boxes[i])
if ioa_j_in_i >= self.SMALL_CONTAINED_IOA:
keep[j] = False
return [bb for bb, k in zip(boxes, keep) if k]
def _assign_players_two_clusters(self, features: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
criteria = (cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, 20, 1.0)
_, labels, centers = cv2.kmeans(
np.float32(features),
K=2,
bestLabels=None,
criteria=criteria,
attempts=5,
flags=cv2.KMEANS_PP_CENTERS,
)
return labels.reshape(-1), centers
def _reclass_extra_goalkeepers(
self,
img_bgr: np.ndarray,
boxes: List[BoundingBox],
cluster_centers: Optional[np.ndarray],
) -> None:
gk_idxs = [i for i, bb in enumerate(boxes) if int(bb.cls_id) == 1]
if len(gk_idxs) <= 1:
return
gk_idxs_sorted = sorted(gk_idxs, key=lambda i: boxes[i].conf, reverse=True)
keep_gk_idx = gk_idxs_sorted[0]
to_reclass = gk_idxs_sorted[1:]
for gki in to_reclass:
hs_gk = self._hs_feature_from_roi(img_bgr, boxes[gki])
if cluster_centers is not None:
d0 = float(np.linalg.norm(hs_gk - cluster_centers[0]))
d1 = float(np.linalg.norm(hs_gk - cluster_centers[1]))
assign_cls = 6 if d0 <= d1 else 7
else:
assign_cls = 6 if float(hs_gk[0]) < self.SINGLE_PLAYER_HUE_PIVOT else 7
boxes[gki].cls_id = int(assign_cls)
def _aggressive_multi_scale_detection(self, img_bgr: np.ndarray) -> List[BoundingBox]:
"""
Aggressive Multi-Scale Object Detection optimized for enumeration and placement.
Uses 5 scales with confidence boosting for small objects.
"""
H, W = img_bgr.shape[:2]
all_detections = []
for scale in self.AGGRESSIVE_SCALES:
if scale != 1.0:
new_h, new_w = int(H * scale), int(W * scale)
# More lenient dimension constraints for aggressive detection
if new_h > 2560 or new_w > 2560 or new_h < 256 or new_w < 256:
continue
scaled_img = cv2.resize(img_bgr, (new_w, new_h))
else:
scaled_img = img_bgr
new_h, new_w = H, W
# Run detection on scaled image
results = self.bbox_model.predict([scaled_img], verbose=False)
if results and hasattr(results[0], "boxes") and results[0].boxes is not None:
for box in results[0].boxes.data:
x1, y1, x2, y2, conf, cls_id = box.tolist()
# Scale coordinates back to original image size
if scale != 1.0:
x1 = x1 / scale
y1 = y1 / scale
x2 = x2 / scale
y2 = y2 / scale
# Clip to original image bounds
x1, y1, x2, y2 = self._clip_box_to_image(x1, y1, x2, y2, W, H)
# Calculate box area for confidence boosting
box_area = (x2 - x1) * (y2 - y1)
# Aggressive confidence boosting based on scale and size
if scale == 1.3 and box_area < 1500: # Very small objects at high scale
conf *= self.SMALL_OBJECT_CONF_BOOST
elif scale == 1.1 and box_area < 3000: # Small objects at medium scale
conf *= 1.10
elif scale == 0.7 and box_area > 15000: # Large objects at small scale
conf *= 1.08
elif scale == 0.9 and box_area > 8000: # Medium-large objects
conf *= 1.05
# Extra boost for small objects regardless of scale
if box_area < 1000:
conf *= 1.12
all_detections.append(BoundingBox(
x1=int(x1), y1=int(y1), x2=int(x2), y2=int(y2),
cls_id=int(cls_id), conf=float(conf)
))
# Apply enumeration-optimized NMS
return self._enumeration_optimized_nms(all_detections)
def _enumeration_optimized_nms(self, boxes: List[BoundingBox]) -> List[BoundingBox]:
"""
Enumeration-optimized NMS with lower threshold to preserve more detections.
"""
if not boxes:
return []
# Group by class for class-specific NMS
boxes_by_class = {}
for box in boxes:
if box.cls_id not in boxes_by_class:
boxes_by_class[box.cls_id] = []
boxes_by_class[box.cls_id].append(box)
final_boxes = []
for cls_id, class_boxes in boxes_by_class.items():
# Sort by confidence
class_boxes_sorted = sorted(class_boxes, key=lambda x: x.conf, reverse=True)
keep = []
while class_boxes_sorted:
# Take the highest confidence box
current = class_boxes_sorted.pop(0)
keep.append(current)
# Remove boxes with high IoU (lower threshold for enumeration)
remaining = []
for box in class_boxes_sorted:
iou = self._calculate_iou(current, box)
if iou < self.ENUMERATION_NMS_THRESHOLD:
remaining.append(box)
elif box.conf > current.conf * 0.95: # Keep very close confidence boxes
remaining.append(box)
class_boxes_sorted = remaining
final_boxes.extend(keep)
return final_boxes
def _calculate_iou(self, box1: BoundingBox, box2: BoundingBox) -> float:
"""Calculate Intersection over Union (IoU) between two bounding boxes."""
# Calculate intersection
x1 = max(box1.x1, box2.x1)
y1 = max(box1.y1, box2.y1)
x2 = min(box1.x2, box2.x2)
y2 = min(box1.y2, box2.y2)
if x2 <= x1 or y2 <= y1:
return 0.0
intersection = (x2 - x1) * (y2 - y1)
# Calculate union
area1 = (box1.x2 - box1.x1) * (box1.y2 - box1.y1)
area2 = (box2.x2 - box2.x1) * (box2.y2 - box2.y1)
union = area1 + area2 - intersection
return intersection / union if union > 0 else 0.0
def predict_batch(
self,
batch_images: List[ndarray],
offset: int,
n_keypoints: int,
task_type: Optional[str] = None,
) -> List[TVFrameResult]:
process_objects = task_type is None or task_type == "object"
process_keypoints = task_type is None or task_type == "keypoint"
bboxes: Dict[int, List[BoundingBox]] = {}
if process_objects:
# Use aggressive multi-scale detection for optimal enumeration and placement
for frame_idx_in_batch, img_bgr in enumerate(batch_images):
boxes = self._aggressive_multi_scale_detection(img_bgr)
# Handle multiple football detections (keep best one)
footballs = [bb for bb in boxes if int(bb.cls_id) == 0]
if len(footballs) > 1:
best_ball = max(footballs, key=lambda b: b.conf)
boxes = [bb for bb in boxes if int(bb.cls_id) != 0]
boxes.append(best_ball)
# Apply more lenient suppression for better enumeration
boxes = self.suppress_quasi_total_containment(boxes)
boxes = self.suppress_small_contained(boxes)
# Team classification for players
player_indices: List[int] = []
player_feats: List[np.ndarray] = []
for i, bb in enumerate(boxes):
if int(bb.cls_id) == 2:
hs = self._hs_feature_from_roi(img_bgr, bb)
player_indices.append(i)
player_feats.append(hs)
cluster_centers: Optional[np.ndarray] = None
n_players = len(player_feats)
if n_players >= 2:
feats = np.vstack(player_feats)
labels, centers = self._assign_players_two_clusters(feats)
order = np.argsort(centers[:, 0])
centers = centers[order]
remap = {old_idx: new_idx for new_idx, old_idx in enumerate(order)}
labels = np.vectorize(remap.get)(labels)
cluster_centers = centers
for idx_in_list, lbl in zip(player_indices, labels):
boxes[idx_in_list].cls_id = 6 if int(lbl) == 0 else 7
elif n_players == 1:
hue, _ = player_feats[0]
boxes[player_indices[0]].cls_id = 6 if float(hue) < self.SINGLE_PLAYER_HUE_PIVOT else 7
self._reclass_extra_goalkeepers(img_bgr, boxes, cluster_centers)
bboxes[offset + frame_idx_in_batch] = boxes
keypoints: Dict[int, List[Tuple[int, int]]] = {}
if process_keypoints:
keypoints_model_results = self.keypoints_model.predict(batch_images)
else:
keypoints_model_results = None
if keypoints_model_results is not None:
for frame_idx_in_batch, detection in enumerate(keypoints_model_results):
if not hasattr(detection, "keypoints") or detection.keypoints is None:
continue
frame_keypoints_with_conf: List[Tuple[int, int, float]] = []
for i, part_points in enumerate(detection.keypoints.data):
for k_id, (x, y, _) in enumerate(part_points):
confidence = float(detection.keypoints.conf[i][k_id])
frame_keypoints_with_conf.append((int(x), int(y), confidence))
if len(frame_keypoints_with_conf) < n_keypoints:
frame_keypoints_with_conf.extend(
[(0, 0, 0.0)] * (n_keypoints - len(frame_keypoints_with_conf))
)
else:
frame_keypoints_with_conf = frame_keypoints_with_conf[:n_keypoints]
filtered_keypoints: List[Tuple[int, int]] = []
for idx, (x, y, confidence) in enumerate(frame_keypoints_with_conf):
if idx in self.CORNER_INDICES:
if confidence < 0.3:
filtered_keypoints.append((0, 0))
else:
filtered_keypoints.append((int(x), int(y)))
else:
if confidence < 0.5:
filtered_keypoints.append((0, 0))
else:
filtered_keypoints.append((int(x), int(y)))
keypoints[offset + frame_idx_in_batch] = filtered_keypoints
results: List[TVFrameResult] = []
for frame_number in range(offset, offset + len(batch_images)):
results.append(
TVFrameResult(
frame_id=frame_number,
boxes=bboxes.get(frame_number, []),
keypoints=keypoints.get(
frame_number,
[(0, 0) for _ in range(n_keypoints)],
),
)
)
return results |