mirror of
https://github.com/blakeblackshear/frigate.git
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579 lines
18 KiB
Python
579 lines
18 KiB
Python
"""Utils for reading and writing object detection data."""
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import datetime
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import logging
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import math
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from collections import defaultdict
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import cv2
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import numpy as np
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from peewee import DoesNotExist
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from frigate.config import DetectConfig, ModelConfig
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from frigate.const import (
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LABEL_CONSOLIDATION_DEFAULT,
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LABEL_CONSOLIDATION_MAP,
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LABEL_NMS_DEFAULT,
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LABEL_NMS_MAP,
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)
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from frigate.detectors.detector_config import PixelFormatEnum
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from frigate.models import Event, Regions, Timeline
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from frigate.util.image import (
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area,
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calculate_region,
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clipped,
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intersection,
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intersection_over_union,
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yuv_region_2_bgr,
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yuv_region_2_rgb,
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yuv_region_2_yuv,
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)
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logger = logging.getLogger(__name__)
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GRID_SIZE = 8
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def get_camera_regions_grid(
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name: str,
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detect: DetectConfig,
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min_region_size: int,
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) -> list[list[dict[str, any]]]:
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"""Build a grid of expected region sizes for a camera."""
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# get grid from db if available
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try:
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regions: Regions = Regions.select().where(Regions.camera == name).get()
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grid = regions.grid
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last_update = regions.last_update
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except DoesNotExist:
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grid = []
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for x in range(GRID_SIZE):
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row = []
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for y in range(GRID_SIZE):
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row.append({"sizes": []})
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grid.append(row)
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last_update = 0
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# get events for timeline entries
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events = (
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Event.select(Event.id)
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.where(Event.camera == name)
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.where((Event.false_positive == None) | (Event.false_positive == False))
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.where(Event.start_time > last_update)
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)
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valid_event_ids = [e["id"] for e in events.dicts()]
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logger.debug(f"Found {len(valid_event_ids)} new events for {name}")
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# no new events, return as is
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if not valid_event_ids:
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return grid
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new_update = datetime.datetime.now().timestamp()
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timeline = (
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Timeline.select(
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*[
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Timeline.camera,
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Timeline.source,
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Timeline.data,
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]
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)
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.where(Timeline.source_id << valid_event_ids)
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.limit(10000)
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.dicts()
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)
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logger.debug(f"Found {len(timeline)} new entries for {name}")
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width = detect.width
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height = detect.height
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for t in timeline:
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if t.get("source") != "tracked_object":
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continue
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box = t["data"]["box"]
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# calculate centroid position
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x = box[0] + (box[2] / 2)
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y = box[1] + (box[3] / 2)
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x_pos = int(x * GRID_SIZE)
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y_pos = int(y * GRID_SIZE)
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calculated_region = calculate_region(
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(height, width),
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box[0] * width,
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box[1] * height,
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(box[0] + box[2]) * width,
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(box[1] + box[3]) * height,
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min_region_size,
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1.35,
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)
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# save width of region to grid as relative
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grid[x_pos][y_pos]["sizes"].append(
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(calculated_region[2] - calculated_region[0]) / width
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)
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for x in range(GRID_SIZE):
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for y in range(GRID_SIZE):
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cell = grid[x][y]
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if len(cell["sizes"]) == 0:
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continue
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std_dev = np.std(cell["sizes"])
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mean = np.mean(cell["sizes"])
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logger.debug(f"std dev: {std_dev} mean: {mean}")
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cell["x"] = x
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cell["y"] = y
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cell["std_dev"] = std_dev
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cell["mean"] = mean
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# update db with new grid
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region = {
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Regions.camera: name,
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Regions.grid: grid,
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Regions.last_update: new_update,
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}
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(
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Regions.insert(region)
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.on_conflict(
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conflict_target=[Regions.camera],
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update=region,
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)
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.execute()
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)
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return grid
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def get_cluster_region_from_grid(frame_shape, min_region, cluster, boxes, region_grid):
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min_x = frame_shape[1]
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min_y = frame_shape[0]
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max_x = 0
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max_y = 0
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for b in cluster:
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min_x = min(boxes[b][0], min_x)
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min_y = min(boxes[b][1], min_y)
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max_x = max(boxes[b][2], max_x)
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max_y = max(boxes[b][3], max_y)
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return get_region_from_grid(
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frame_shape, [min_x, min_y, max_x, max_y], min_region, region_grid
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)
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def get_region_from_grid(
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frame_shape: tuple[int],
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cluster: list[int],
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min_region: int,
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region_grid: list[list[dict[str, any]]],
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) -> list[int]:
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"""Get a region for a box based on the region grid."""
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box = calculate_region(
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frame_shape, cluster[0], cluster[1], cluster[2], cluster[3], min_region
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)
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centroid = (
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box[0] + (min(frame_shape[1], box[2]) - box[0]) / 2,
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box[1] + (min(frame_shape[0], box[3]) - box[1]) / 2,
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)
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grid_x = int(centroid[0] / frame_shape[1] * GRID_SIZE)
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grid_y = int(centroid[1] / frame_shape[0] * GRID_SIZE)
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cell = region_grid[grid_x][grid_y]
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# if there is no known data, use original region calculation
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if not cell or not cell["sizes"]:
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return box
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# convert the calculated region size to relative
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calc_size = (box[2] - box[0]) / frame_shape[1]
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# if region is within expected size, don't resize
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if (
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(cell["mean"] - cell["std_dev"])
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<= calc_size
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<= (cell["mean"] + cell["std_dev"])
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):
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return box
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# TODO not sure how to handle case where cluster is larger than expected region
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elif calc_size > (cell["mean"] + cell["std_dev"]):
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return box
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size = cell["mean"] * frame_shape[1]
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# get region based on grid size
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return calculate_region(
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frame_shape,
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max(0, centroid[0] - size / 2),
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max(0, centroid[1] - size / 2),
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min(frame_shape[1], centroid[0] + size / 2),
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min(frame_shape[0], centroid[1] + size / 2),
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min_region,
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)
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def is_object_filtered(obj, objects_to_track, object_filters):
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object_name = obj[0]
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object_score = obj[1]
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object_box = obj[2]
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object_area = obj[3]
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object_ratio = obj[4]
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if object_name not in objects_to_track:
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return True
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if object_name in object_filters:
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obj_settings = object_filters[object_name]
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# if the min area is larger than the
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# detected object, don't add it to detected objects
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if obj_settings.min_area > object_area:
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return True
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# if the detected object is larger than the
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# max area, don't add it to detected objects
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if obj_settings.max_area < object_area:
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return True
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# if the score is lower than the min_score, skip
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if obj_settings.min_score > object_score:
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return True
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# if the object is not proportionally wide enough
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if obj_settings.min_ratio > object_ratio:
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return True
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# if the object is proportionally too wide
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if obj_settings.max_ratio < object_ratio:
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return True
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if obj_settings.mask is not None:
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# compute the coordinates of the object and make sure
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# the location isn't outside the bounds of the image (can happen from rounding)
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object_xmin = object_box[0]
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object_xmax = object_box[2]
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object_ymax = object_box[3]
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y_location = min(int(object_ymax), len(obj_settings.mask) - 1)
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x_location = min(
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int((object_xmax + object_xmin) / 2.0),
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len(obj_settings.mask[0]) - 1,
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)
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# if the object is in a masked location, don't add it to detected objects
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if obj_settings.mask[y_location][x_location] == 0:
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return True
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return False
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def get_min_region_size(model_config: ModelConfig) -> int:
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"""Get the min region size."""
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return max(model_config.height, model_config.width)
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def create_tensor_input(frame, model_config: ModelConfig, region):
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if model_config.input_pixel_format == PixelFormatEnum.rgb:
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cropped_frame = yuv_region_2_rgb(frame, region)
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elif model_config.input_pixel_format == PixelFormatEnum.bgr:
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cropped_frame = yuv_region_2_bgr(frame, region)
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else:
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cropped_frame = yuv_region_2_yuv(frame, region)
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# Resize if needed
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if cropped_frame.shape != (model_config.height, model_config.width, 3):
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cropped_frame = cv2.resize(
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cropped_frame,
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dsize=(model_config.width, model_config.height),
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interpolation=cv2.INTER_LINEAR,
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)
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# Expand dimensions since the model expects images to have shape: [1, height, width, 3]
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return np.expand_dims(cropped_frame, axis=0)
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def box_overlaps(b1, b2):
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if b1[2] < b2[0] or b1[0] > b2[2] or b1[1] > b2[3] or b1[3] < b2[1]:
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return False
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return True
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def box_inside(b1, b2):
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# check if b2 is inside b1
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if b2[0] >= b1[0] and b2[1] >= b1[1] and b2[2] <= b1[2] and b2[3] <= b1[3]:
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return True
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return False
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def reduce_boxes(boxes, iou_threshold=0.0):
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clusters = []
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for box in boxes:
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matched = 0
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for cluster in clusters:
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if intersection_over_union(box, cluster) > iou_threshold:
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matched = 1
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cluster[0] = min(cluster[0], box[0])
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cluster[1] = min(cluster[1], box[1])
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cluster[2] = max(cluster[2], box[2])
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cluster[3] = max(cluster[3], box[3])
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if not matched:
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clusters.append(list(box))
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return [tuple(c) for c in clusters]
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def average_boxes(boxes: list[list[int, int, int, int]]) -> list[int, int, int, int]:
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"""Return a box that is the average of a list of boxes."""
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x_mins = []
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y_mins = []
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x_max = []
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y_max = []
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for box in boxes:
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x_mins.append(box[0])
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y_mins.append(box[1])
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x_max.append(box[2])
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y_max.append(box[3])
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return [np.mean(x_mins), np.mean(y_mins), np.mean(x_max), np.mean(y_max)]
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def median_of_boxes(boxes: list[list[int, int, int, int]]) -> list[int, int, int, int]:
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"""Return a box that is the median of a list of boxes."""
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sorted_boxes = sorted(boxes, key=lambda x: area(x))
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return sorted_boxes[int(len(sorted_boxes) / 2.0)]
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def intersects_any(box_a, boxes):
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for box in boxes:
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if box_overlaps(box_a, box):
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return True
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return False
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def inside_any(box_a, boxes):
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for box in boxes:
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# check if box_a is inside of box
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if box_inside(box, box_a):
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return True
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return False
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def get_cluster_boundary(box, min_region):
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# compute the max region size for the current box (box is 10% of region)
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box_width = box[2] - box[0]
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box_height = box[3] - box[1]
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max_region_area = abs(box_width * box_height) / 0.1
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max_region_size = max(min_region, int(math.sqrt(max_region_area)))
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centroid = (box_width / 2 + box[0], box_height / 2 + box[1])
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max_x_dist = int(max_region_size - box_width / 2 * 1.1)
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max_y_dist = int(max_region_size - box_height / 2 * 1.1)
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return [
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int(centroid[0] - max_x_dist),
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int(centroid[1] - max_y_dist),
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int(centroid[0] + max_x_dist),
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int(centroid[1] + max_y_dist),
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]
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def get_cluster_candidates(frame_shape, min_region, boxes):
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# and create a cluster of other boxes using it's max region size
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# only include boxes where the region is an appropriate(except the region could possibly be smaller?)
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# size in the cluster. in order to be in the cluster, the furthest corner needs to be within x,y offset
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# determined by the max_region size minus half the box + 20%
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# TODO: see if we can do this with numpy
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cluster_candidates = []
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used_boxes = []
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# loop over each box
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for current_index, b in enumerate(boxes):
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if current_index in used_boxes:
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continue
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cluster = [current_index]
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used_boxes.append(current_index)
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cluster_boundary = get_cluster_boundary(b, min_region)
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# find all other boxes that fit inside the boundary
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for compare_index, compare_box in enumerate(boxes):
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if compare_index in used_boxes:
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continue
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# if the box is not inside the potential cluster area, cluster them
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if not box_inside(cluster_boundary, compare_box):
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continue
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# get the region if you were to add this box to the cluster
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potential_cluster = cluster + [compare_index]
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cluster_region = get_cluster_region(
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frame_shape, min_region, potential_cluster, boxes
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)
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# if region could be smaller and either box would be too small
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# for the resulting region, dont cluster
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should_cluster = True
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if (cluster_region[2] - cluster_region[0]) > min_region:
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for b in potential_cluster:
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box = boxes[b]
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# boxes should be more than 5% of the area of the region
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if area(box) / area(cluster_region) < 0.05:
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should_cluster = False
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break
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if should_cluster:
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cluster.append(compare_index)
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used_boxes.append(compare_index)
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cluster_candidates.append(cluster)
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# return the unique clusters only
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unique = {tuple(sorted(c)) for c in cluster_candidates}
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return [list(tup) for tup in unique]
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def get_cluster_region(frame_shape, min_region, cluster, boxes):
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min_x = frame_shape[1]
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min_y = frame_shape[0]
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max_x = 0
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max_y = 0
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for b in cluster:
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min_x = min(boxes[b][0], min_x)
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min_y = min(boxes[b][1], min_y)
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max_x = max(boxes[b][2], max_x)
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max_y = max(boxes[b][3], max_y)
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return calculate_region(
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frame_shape, min_x, min_y, max_x, max_y, min_region, multiplier=1.35
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)
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def get_startup_regions(
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frame_shape: tuple[int],
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region_min_size: int,
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region_grid: list[list[dict[str, any]]],
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) -> list[list[int]]:
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"""Get a list of regions to run on startup."""
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# return 8 most popular regions for the camera
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all_cells = np.concatenate(region_grid).flat
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startup_cells = sorted(all_cells, key=lambda c: len(c["sizes"]), reverse=True)[0:8]
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regions = []
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for cell in startup_cells:
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# rest of the cells are empty
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if not cell["sizes"]:
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break
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x = frame_shape[1] / GRID_SIZE * (0.5 + cell["x"])
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y = frame_shape[0] / GRID_SIZE * (0.5 + cell["y"])
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size = cell["mean"] * frame_shape[1]
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regions.append(
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calculate_region(
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frame_shape,
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x - size / 2,
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y - size / 2,
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x + size / 2,
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y + size / 2,
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region_min_size,
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multiplier=1,
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)
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)
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return regions
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def reduce_detections(
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frame_shape: tuple[int],
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all_detections: list[tuple[any]],
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) -> list[tuple[any]]:
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"""Take a list of detections and reduce overlaps to create a list of confident detections."""
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def reduce_overlapping_detections(detections: list[tuple[any]]) -> list[tuple[any]]:
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"""apply non-maxima suppression to suppress weak, overlapping bounding boxes."""
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detected_object_groups = defaultdict(lambda: [])
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for detection in detections:
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detected_object_groups[detection[0]].append(detection)
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selected_objects = []
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for group in detected_object_groups.values():
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label = group[0][0]
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# o[2] is the box of the object: xmin, ymin, xmax, ymax
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# apply max/min to ensure values do not exceed the known frame size
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boxes = [
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(
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o[2][0],
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o[2][1],
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o[2][2] - o[2][0],
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o[2][3] - o[2][1],
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)
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for o in group
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]
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# reduce confidences for objects that are on edge of region
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# 0.6 should be used to ensure that the object is still considered and not dropped
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# due to min score requirement of NMSBoxes
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confidences = [0.6 if clipped(o, frame_shape) else o[1] for o in group]
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|
|
|
indices = cv2.dnn.NMSBoxes(
|
|
boxes, confidences, 0.5, LABEL_NMS_MAP.get(label, LABEL_NMS_DEFAULT)
|
|
)
|
|
|
|
# add objects
|
|
for index in indices:
|
|
index = index if isinstance(index, np.int32) else index[0]
|
|
obj = group[index]
|
|
selected_objects.append(obj)
|
|
|
|
# set the detections list to only include top objects
|
|
return selected_objects
|
|
|
|
def get_consolidated_object_detections(detections: list[tuple[any]]):
|
|
"""Drop detections that overlap too much."""
|
|
detected_object_groups = defaultdict(lambda: [])
|
|
for detection in detections:
|
|
detected_object_groups[detection[0]].append(detection)
|
|
|
|
consolidated_detections = []
|
|
for group in detected_object_groups.values():
|
|
# if the group only has 1 item, skip
|
|
if len(group) == 1:
|
|
consolidated_detections.append(group[0])
|
|
continue
|
|
|
|
# sort smallest to largest by area
|
|
sorted_by_area = sorted(group, key=lambda g: g[3])
|
|
|
|
for current_detection_idx in range(0, len(sorted_by_area)):
|
|
current_detection = sorted_by_area[current_detection_idx]
|
|
current_label = current_detection[0]
|
|
current_box = current_detection[2]
|
|
overlap = 0
|
|
for to_check_idx in range(
|
|
min(current_detection_idx + 1, len(sorted_by_area)),
|
|
len(sorted_by_area),
|
|
):
|
|
to_check = sorted_by_area[to_check_idx][2]
|
|
|
|
# if area of current detection / area of check < 5% they should not be compared
|
|
# this covers cases where a large car parked in a driveway doesn't block detections
|
|
# of cars in the street behind it
|
|
if area(current_box) / area(to_check) < 0.05:
|
|
continue
|
|
|
|
intersect_box = intersection(current_box, to_check)
|
|
# if % of smaller detection is inside of another detection, consolidate
|
|
if intersect_box is not None and area(intersect_box) / area(
|
|
current_box
|
|
) > LABEL_CONSOLIDATION_MAP.get(
|
|
current_label, LABEL_CONSOLIDATION_DEFAULT
|
|
):
|
|
overlap = 1
|
|
break
|
|
if overlap == 0:
|
|
consolidated_detections.append(
|
|
sorted_by_area[current_detection_idx]
|
|
)
|
|
|
|
return consolidated_detections
|
|
|
|
return get_consolidated_object_detections(
|
|
reduce_overlapping_detections(all_detections)
|
|
)
|