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Object_tracking_boxmot / tracking /ultralytics /engine /predictor.py

usiddiquee

e1832f4 9 months ago

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	# Ultralytics 🚀 AGPL-3.0 License - https://ultralytics.com/license
	"""
	Run prediction on images, videos, directories, globs, YouTube, webcam, streams, etc.

	Usage - sources:
	$ yolo mode=predict model=yolo11n.pt source=0 # webcam
	img.jpg # image
	vid.mp4 # video
	screen # screenshot
	path/ # directory
	list.txt # list of images
	list.streams # list of streams
	'path/*.jpg' # glob
	'https://youtu.be/LNwODJXcvt4' # YouTube
	'rtsp://example.com/media.mp4' # RTSP, RTMP, HTTP, TCP stream

	Usage - formats:
	$ yolo mode=predict model=yolo11n.pt # PyTorch
	yolo11n.torchscript # TorchScript
	yolo11n.onnx # ONNX Runtime or OpenCV DNN with dnn=True
	yolo11n_openvino_model # OpenVINO
	yolo11n.engine # TensorRT
	yolo11n.mlpackage # CoreML (macOS-only)
	yolo11n_saved_model # TensorFlow SavedModel
	yolo11n.pb # TensorFlow GraphDef
	yolo11n.tflite # TensorFlow Lite
	yolo11n_edgetpu.tflite # TensorFlow Edge TPU
	yolo11n_paddle_model # PaddlePaddle
	yolo11n.mnn # MNN
	yolo11n_ncnn_model # NCNN
	yolo11n_imx_model # Sony IMX
	yolo11n_rknn_model # Rockchip RKNN
	"""

	import platform
	import re
	import threading
	from pathlib import Path

	import cv2
	import numpy as np
	import torch

	from ultralytics.cfg import get_cfg, get_save_dir
	from ultralytics.data import load_inference_source
	from ultralytics.data.augment import LetterBox, classify_transforms
	from ultralytics.nn.autobackend import AutoBackend
	from ultralytics.utils import DEFAULT_CFG, LOGGER, MACOS, WINDOWS, callbacks, colorstr, ops
	from ultralytics.utils.checks import check_imgsz, check_imshow
	from ultralytics.utils.files import increment_path
	from ultralytics.utils.torch_utils import select_device, smart_inference_mode

	STREAM_WARNING = """
	WARNING ⚠️ inference results will accumulate in RAM unless `stream=True` is passed, causing potential out-of-memory
	errors for large sources or long-running streams and videos. See https://docs.ultralytics.com/modes/predict/ for help.

	Example:
	results = model(source=..., stream=True) # generator of Results objects
	for r in results:
	boxes = r.boxes # Boxes object for bbox outputs
	masks = r.masks # Masks object for segment masks outputs
	probs = r.probs # Class probabilities for classification outputs
	"""


	class BasePredictor:
	"""
	A base class for creating predictors.

	This class provides the foundation for prediction functionality, handling model setup, inference,
	and result processing across various input sources.

	Attributes:
	args (SimpleNamespace): Configuration for the predictor.
	save_dir (Path): Directory to save results.
	done_warmup (bool): Whether the predictor has finished setup.
	model (torch.nn.Module): Model used for prediction.
	data (dict): Data configuration.
	device (torch.device): Device used for prediction.
	dataset (Dataset): Dataset used for prediction.
	vid_writer (dict): Dictionary of {save_path: video_writer} for saving video output.
	plotted_img (numpy.ndarray): Last plotted image.
	source_type (SimpleNamespace): Type of input source.
	seen (int): Number of images processed.
	windows (list): List of window names for visualization.
	batch (tuple): Current batch data.
	results (list): Current batch results.
	transforms (callable): Image transforms for classification.
	callbacks (dict): Callback functions for different events.
	txt_path (Path): Path to save text results.
	_lock (threading.Lock): Lock for thread-safe inference.

	Methods:
	preprocess: Prepare input image before inference.
	inference: Run inference on a given image.
	postprocess: Process raw predictions into structured results.
	predict_cli: Run prediction for command line interface.
	setup_source: Set up input source and inference mode.
	stream_inference: Stream inference on input source.
	setup_model: Initialize and configure the model.
	write_results: Write inference results to files.
	save_predicted_images: Save prediction visualizations.
	show: Display results in a window.
	run_callbacks: Execute registered callbacks for an event.
	add_callback: Register a new callback function.
	"""

	def __init__(self, cfg=DEFAULT_CFG, overrides=None, _callbacks=None):
	"""
	Initialize the BasePredictor class.

	Args:
	cfg (str \| dict): Path to a configuration file or a configuration dictionary.
	overrides (dict \| None): Configuration overrides.
	_callbacks (dict \| None): Dictionary of callback functions.
	"""
	self.args = get_cfg(cfg, overrides)
	self.save_dir = get_save_dir(self.args)
	if self.args.conf is None:
	self.args.conf = 0.25 # default conf=0.25
	self.done_warmup = False
	if self.args.show:
	self.args.show = check_imshow(warn=True)

	# Usable if setup is done
	self.model = None
	self.data = self.args.data # data_dict
	self.imgsz = None
	self.device = None
	self.dataset = None
	self.vid_writer = {} # dict of {save_path: video_writer, ...}
	self.plotted_img = None
	self.source_type = None
	self.seen = 0
	self.windows = []
	self.batch = None
	self.results = None
	self.transforms = None
	self.callbacks = _callbacks or callbacks.get_default_callbacks()
	self.txt_path = None
	self._lock = threading.Lock() # for automatic thread-safe inference
	callbacks.add_integration_callbacks(self)

	def preprocess(self, im):
	"""
	Prepares input image before inference.

	Args:
	im (torch.Tensor \| List(np.ndarray)): Images of shape (N, 3, h, w) for tensor, [(h, w, 3) x N] for list.
	"""
	not_tensor = not isinstance(im, torch.Tensor)
	if not_tensor:
	im = np.stack(self.pre_transform(im))
	im = im[..., ::-1].transpose((0, 3, 1, 2)) # BGR to RGB, BHWC to BCHW, (n, 3, h, w)
	im = np.ascontiguousarray(im) # contiguous
	im = torch.from_numpy(im)

	im = im.to(self.device)
	im = im.half() if self.model.fp16 else im.float() # uint8 to fp16/32
	if not_tensor:
	im /= 255 # 0 - 255 to 0.0 - 1.0
	return im

	def inference(self, im, args, *kwargs):
	"""Run inference on a given image using the specified model and arguments."""
	visualize = (
	increment_path(self.save_dir / Path(self.batch[0][0]).stem, mkdir=True)
	if self.args.visualize and (not self.source_type.tensor)
	else False
	)
	return self.model(im, augment=self.args.augment, visualize=visualize, embed=self.args.embed, args, *kwargs)

	def pre_transform(self, im):
	"""
	Pre-transform input image before inference.

	Args:
	im (List[np.ndarray]): Images of shape (N, 3, h, w) for tensor, [(h, w, 3) x N] for list.

	Returns:
	(List[np.ndarray]): A list of transformed images.
	"""
	same_shapes = len({x.shape for x in im}) == 1
	letterbox = LetterBox(
	self.imgsz,
	auto=same_shapes and (self.model.pt or (getattr(self.model, "dynamic", False) and not self.model.imx)),
	stride=self.model.stride,
	)
	return [letterbox(image=x) for x in im]

	def postprocess(self, preds, img, orig_imgs):
	"""Post-process predictions for an image and return them."""
	return preds

	def __call__(self, source=None, model=None, stream=False, args, *kwargs):
	"""
	Perform inference on an image or stream.

	Args:
	source (str \| Path \| List[str] \| List[Path] \| List[np.ndarray] \| np.ndarray \| torch.Tensor \| None):
	Source for inference.
	model (str \| Path \| torch.nn.Module \| None): Model for inference.
	stream (bool): Whether to stream the inference results. If True, returns a generator.
	*args (Any): Additional arguments for the inference method.
	**kwargs (Any): Additional keyword arguments for the inference method.

	Returns:
	(List[ultralytics.engine.results.Results] \| generator): Results objects or generator of Results objects.
	"""
	self.stream = stream
	if stream:
	return self.stream_inference(source, model, args, *kwargs)
	else:
	return list(self.stream_inference(source, model, args, *kwargs)) # merge list of Result into one

	def predict_cli(self, source=None, model=None):
	"""
	Method used for Command Line Interface (CLI) prediction.

	This function is designed to run predictions using the CLI. It sets up the source and model, then processes
	the inputs in a streaming manner. This method ensures that no outputs accumulate in memory by consuming the
	generator without storing results.

	Args:
	source (str \| Path \| List[str] \| List[Path] \| List[np.ndarray] \| np.ndarray \| torch.Tensor \| None):
	Source for inference.
	model (str \| Path \| torch.nn.Module \| None): Model for inference.

	Note:
	Do not modify this function or remove the generator. The generator ensures that no outputs are
	accumulated in memory, which is critical for preventing memory issues during long-running predictions.
	"""
	gen = self.stream_inference(source, model)
	for _ in gen: # sourcery skip: remove-empty-nested-block, noqa
	pass

	def setup_source(self, source):
	"""
	Set up source and inference mode.

	Args:
	source (str \| Path \| List[str] \| List[Path] \| List[np.ndarray] \| np.ndarray \| torch.Tensor):
	Source for inference.
	"""
	self.imgsz = check_imgsz(self.args.imgsz, stride=self.model.stride, min_dim=2) # check image size
	self.transforms = (
	getattr(
	self.model.model,
	"transforms",
	classify_transforms(self.imgsz[0], crop_fraction=self.args.crop_fraction),
	)
	if self.args.task == "classify"
	else None
	)
	self.dataset = load_inference_source(
	source=source,
	batch=self.args.batch,
	vid_stride=self.args.vid_stride,
	buffer=self.args.stream_buffer,
	)
	self.source_type = self.dataset.source_type
	if not getattr(self, "stream", True) and (
	self.source_type.stream
	or self.source_type.screenshot
	or len(self.dataset) > 1000 # many images
	or any(getattr(self.dataset, "video_flag", [False]))
	): # videos
	LOGGER.warning(STREAM_WARNING)
	self.vid_writer = {}

	@smart_inference_mode()
	def stream_inference(self, source=None, model=None, args, *kwargs):
	"""
	Stream real-time inference on camera feed and save results to file.

	Args:
	source (str \| Path \| List[str] \| List[Path] \| List[np.ndarray] \| np.ndarray \| torch.Tensor \| None):
	Source for inference.
	model (str \| Path \| torch.nn.Module \| None): Model for inference.
	*args (Any): Additional arguments for the inference method.
	**kwargs (Any): Additional keyword arguments for the inference method.

	Yields:
	(ultralytics.engine.results.Results): Results objects.
	"""
	if self.args.verbose:
	LOGGER.info("")

	# Setup model
	if not self.model:
	self.setup_model(model)

	with self._lock: # for thread-safe inference
	# Setup source every time predict is called
	self.setup_source(source if source is not None else self.args.source)

	# Check if save_dir/ label file exists
	if self.args.save or self.args.save_txt:
	(self.save_dir / "labels" if self.args.save_txt else self.save_dir).mkdir(parents=True, exist_ok=True)

	# Warmup model
	if not self.done_warmup:
	self.model.warmup(imgsz=(1 if self.model.pt or self.model.triton else self.dataset.bs, 3, *self.imgsz))
	self.done_warmup = True

	self.seen, self.windows, self.batch = 0, [], None
	profilers = (
	ops.Profile(device=self.device),
	ops.Profile(device=self.device),
	ops.Profile(device=self.device),
	)
	self.run_callbacks("on_predict_start")
	for self.batch in self.dataset:
	self.run_callbacks("on_predict_batch_start")
	paths, im0s, s = self.batch

	# Preprocess
	with profilers[0]:
	im = self.preprocess(im0s)

	# Inference
	with profilers[1]:
	preds = self.inference(im, args, *kwargs)
	if self.args.embed:
	yield from [preds] if isinstance(preds, torch.Tensor) else preds # yield embedding tensors
	continue

	# Postprocess
	with profilers[2]:
	self.results = self.postprocess(preds, im, im0s)
	self.run_callbacks("on_predict_postprocess_end")

	# Visualize, save, write results
	n = len(im0s)
	for i in range(n):
	self.seen += 1
	self.results[i].speed = {
	"preprocess": profilers[0].dt * 1e3 / n,
	"inference": profilers[1].dt * 1e3 / n,
	"postprocess": profilers[2].dt * 1e3 / n,
	}
	if self.args.verbose or self.args.save or self.args.save_txt or self.args.show:
	s[i] += self.write_results(i, Path(paths[i]), im, s)

	# Print batch results
	if self.args.verbose:
	LOGGER.info("\n".join(s))

	self.run_callbacks("on_predict_batch_end")
	yield from self.results

	# Release assets
	for v in self.vid_writer.values():
	if isinstance(v, cv2.VideoWriter):
	v.release()

	# Print final results
	if self.args.verbose and self.seen:
	t = tuple(x.t / self.seen * 1e3 for x in profilers) # speeds per image
	LOGGER.info(
	f"Speed: %.1fms preprocess, %.1fms inference, %.1fms postprocess per image at shape "
	f"{(min(self.args.batch, self.seen), 3, *im.shape[2:])}" % t
	)
	if self.args.save or self.args.save_txt or self.args.save_crop:
	nl = len(list(self.save_dir.glob("labels/*.txt"))) # number of labels
	s = f"\n{nl} label{'s' * (nl > 1)} saved to {self.save_dir / 'labels'}" if self.args.save_txt else ""
	LOGGER.info(f"Results saved to {colorstr('bold', self.save_dir)}{s}")
	self.run_callbacks("on_predict_end")

	def setup_model(self, model, verbose=True):
	"""
	Initialize YOLO model with given parameters and set it to evaluation mode.

	Args:
	model (str \| Path \| torch.nn.Module \| None): Model to load or use.
	verbose (bool): Whether to print verbose output.
	"""
	self.model = AutoBackend(
	weights=model or self.args.model,
	device=select_device(self.args.device, verbose=verbose),
	dnn=self.args.dnn,
	data=self.args.data,
	fp16=self.args.half,
	batch=self.args.batch,
	fuse=True,
	verbose=verbose,
	)

	self.device = self.model.device # update device
	self.args.half = self.model.fp16 # update half
	self.model.eval()

	def write_results(self, i, p, im, s):
	"""
	Write inference results to a file or directory.

	Args:
	i (int): Index of the current image in the batch.
	p (Path): Path to the current image.
	im (torch.Tensor): Preprocessed image tensor.
	s (List[str]): List of result strings.

	Returns:
	(str): String with result information.
	"""
	string = "" # print string
	if len(im.shape) == 3:
	im = im[None] # expand for batch dim
	if self.source_type.stream or self.source_type.from_img or self.source_type.tensor: # batch_size >= 1
	string += f"{i}: "
	frame = self.dataset.count
	else:
	match = re.search(r"frame (\d+)/", s[i])
	frame = int(match[1]) if match else None # 0 if frame undetermined

	self.txt_path = self.save_dir / "labels" / (p.stem + ("" if self.dataset.mode == "image" else f"_{frame}"))
	string += "{:g}x{:g} ".format(*im.shape[2:])
	result = self.results[i]
	result.save_dir = self.save_dir.__str__() # used in other locations
	string += f"{result.verbose()}{result.speed['inference']:.1f}ms"

	# Add predictions to image
	if self.args.save or self.args.show:
	self.plotted_img = result.plot(
	line_width=self.args.line_width,
	boxes=self.args.show_boxes,
	conf=self.args.show_conf,
	labels=self.args.show_labels,
	im_gpu=None if self.args.retina_masks else im[i],
	)

	# Save results
	if self.args.save_txt:
	result.save_txt(f"{self.txt_path}.txt", save_conf=self.args.save_conf)
	if self.args.save_crop:
	result.save_crop(save_dir=self.save_dir / "crops", file_name=self.txt_path.stem)
	if self.args.show:
	self.show(str(p))
	if self.args.save:
	self.save_predicted_images(str(self.save_dir / p.name), frame)

	return string

	def save_predicted_images(self, save_path="", frame=0):
	"""
	Save video predictions as mp4 or images as jpg at specified path.

	Args:
	save_path (str): Path to save the results.
	frame (int): Frame number for video mode.
	"""
	im = self.plotted_img

	# Save videos and streams
	if self.dataset.mode in {"stream", "video"}:
	fps = self.dataset.fps if self.dataset.mode == "video" else 30
	frames_path = f"{save_path.split('.', 1)[0]}_frames/"
	if save_path not in self.vid_writer: # new video
	if self.args.save_frames:
	Path(frames_path).mkdir(parents=True, exist_ok=True)
	suffix, fourcc = (".mp4", "avc1") if MACOS else (".avi", "WMV2") if WINDOWS else (".avi", "MJPG")
	self.vid_writer[save_path] = cv2.VideoWriter(
	filename=str(Path(save_path).with_suffix(suffix)),
	fourcc=cv2.VideoWriter_fourcc(*fourcc),
	fps=fps, # integer required, floats produce error in MP4 codec
	frameSize=(im.shape[1], im.shape[0]), # (width, height)
	)

	# Save video
	self.vid_writer[save_path].write(im)
	if self.args.save_frames:
	cv2.imwrite(f"{frames_path}{frame}.jpg", im)

	# Save images
	else:
	cv2.imwrite(str(Path(save_path).with_suffix(".jpg")), im) # save to JPG for best support

	def show(self, p=""):
	"""Display an image in a window."""
	im = self.plotted_img
	if platform.system() == "Linux" and p not in self.windows:
	self.windows.append(p)
	cv2.namedWindow(p, cv2.WINDOW_NORMAL \| cv2.WINDOW_KEEPRATIO) # allow window resize (Linux)
	cv2.resizeWindow(p, im.shape[1], im.shape[0]) # (width, height)
	cv2.imshow(p, im)
	cv2.waitKey(300 if self.dataset.mode == "image" else 1) # 1 millisecond

	def run_callbacks(self, event: str):
	"""Run all registered callbacks for a specific event."""
	for callback in self.callbacks.get(event, []):
	callback(self)

	def add_callback(self, event: str, func):
	"""Add a callback function for a specific event."""
	self.callbacks[event].append(func)