pose-detect/ultralytics/models/yolo/detect/train.py

# Ultralytics YOLO 🚀, AGPL-3.0 license

import math
import random
from copy import copy

import numpy as np
import torch.nn as nn

from ultralytics.data import build_dataloader, build_yolo_dataset
from ultralytics.engine.trainer import BaseTrainer
from ultralytics.models import yolo
from ultralytics.nn.tasks import DetectionModel
from ultralytics.utils import LOGGER, RANK
from ultralytics.utils.plotting import plot_images, plot_labels, plot_results
from ultralytics.utils.torch_utils import de_parallel, torch_distributed_zero_first


class DetectionTrainer(BaseTrainer):
    """
    A class extending the BaseTrainer class for training based on a detection model.

    Example:
        ```python
        from ultralytics.models.yolo.detect import DetectionTrainer

        args = dict(model='yolov8n.pt', data='coco8.yaml', epochs=3)
        trainer = DetectionTrainer(overrides=args)
        trainer.train()
        ```
    """

    def build_dataset(self, img_path, mode="train", batch=None):
        """
        Build YOLO Dataset.

        Args:
            img_path (str): Path to the folder containing images.
            mode (str): `train` mode or `val` mode, users are able to customize different augmentations for each mode.
            batch (int, optional): Size of batches, this is for `rect`. Defaults to None.
        """
        gs = max(int(de_parallel(self.model).stride.max() if self.model else 0), 32)
        return build_yolo_dataset(self.args, img_path, batch, self.data, mode=mode, rect=mode == "val", stride=gs)

    def get_dataloader(self, dataset_path, batch_size=16, rank=0, mode="train"):
        """Construct and return dataloader."""
        assert mode in {"train", "val"}, f"Mode must be 'train' or 'val', not {mode}."
        with torch_distributed_zero_first(rank):  # init dataset *.cache only once if DDP
            dataset = self.build_dataset(dataset_path, mode, batch_size)
        shuffle = mode == "train"
        if getattr(dataset, "rect", False) and shuffle:
            LOGGER.warning("WARNING ⚠️ 'rect=True' is incompatible with DataLoader shuffle, setting shuffle=False")
            shuffle = False
        workers = self.args.workers if mode == "train" else self.args.workers * 2
        return build_dataloader(dataset, batch_size, workers, shuffle, rank)  # return dataloader

    def preprocess_batch(self, batch):
        """Preprocesses a batch of images by scaling and converting to float."""
        batch["img"] = batch["img"].to(self.device, non_blocking=True).float() / 255
        if self.args.multi_scale:
            imgs = batch["img"]
            sz = (
                random.randrange(self.args.imgsz * 0.5, self.args.imgsz * 1.5 + self.stride)
                // self.stride
                * self.stride
            )  # size
            sf = sz / max(imgs.shape[2:])  # scale factor
            if sf != 1:
                ns = [
                    math.ceil(x * sf / self.stride) * self.stride for x in imgs.shape[2:]
                ]  # new shape (stretched to gs-multiple)
                imgs = nn.functional.interpolate(imgs, size=ns, mode="bilinear", align_corners=False)
            batch["img"] = imgs
        return batch

    def set_model_attributes(self):
        """Nl = de_parallel(self.model).model[-1].nl  # number of detection layers (to scale hyps)."""
        # self.args.box *= 3 / nl  # scale to layers
        # self.args.cls *= self.data["nc"] / 80 * 3 / nl  # scale to classes and layers
        # self.args.cls *= (self.args.imgsz / 640) ** 2 * 3 / nl  # scale to image size and layers
        self.model.nc = self.data["nc"]  # attach number of classes to model
        self.model.names = self.data["names"]  # attach class names to model
        self.model.args = self.args  # attach hyperparameters to model
        # TODO: self.model.class_weights = labels_to_class_weights(dataset.labels, nc).to(device) * nc

    def get_model(self, cfg=None, weights=None, verbose=True):
        """Return a YOLO detection model."""
        model = DetectionModel(cfg, nc=self.data["nc"], verbose=verbose and RANK == -1)
        if weights:
            model.load(weights)
        return model

    def get_validator(self):
        """Returns a DetectionValidator for YOLO model validation."""
        self.loss_names = "box_loss", "cls_loss", "dfl_loss"
        return yolo.detect.DetectionValidator(
            self.test_loader, save_dir=self.save_dir, args=copy(self.args), _callbacks=self.callbacks
        )

    def label_loss_items(self, loss_items=None, prefix="train"):
        """
        Returns a loss dict with labelled training loss items tensor.

        Not needed for classification but necessary for segmentation & detection
        """
        keys = [f"{prefix}/{x}" for x in self.loss_names]
        if loss_items is not None:
            loss_items = [round(float(x), 5) for x in loss_items]  # convert tensors to 5 decimal place floats
            return dict(zip(keys, loss_items))
        else:
            return keys

    def progress_string(self):
        """Returns a formatted string of training progress with epoch, GPU memory, loss, instances and size."""
        return ("\n" + "%11s" * (4 + len(self.loss_names))) % (
            "Epoch",
            "GPU_mem",
            *self.loss_names,
            "Instances",
            "Size",
        )

    def plot_training_samples(self, batch, ni):
        """Plots training samples with their annotations."""
        plot_images(
            images=batch["img"],
            batch_idx=batch["batch_idx"],
            cls=batch["cls"].squeeze(-1),
            bboxes=batch["bboxes"],
            paths=batch["im_file"],
            fname=self.save_dir / f"train_batch{ni}.jpg",
            on_plot=self.on_plot,
        )

    def plot_metrics(self):
        """Plots metrics from a CSV file."""
        plot_results(file=self.csv, on_plot=self.on_plot)  # save results.png

    def plot_training_labels(self):
        """Create a labeled training plot of the YOLO model."""
        boxes = np.concatenate([lb["bboxes"] for lb in self.train_loader.dataset.labels], 0)
        cls = np.concatenate([lb["cls"] for lb in self.train_loader.dataset.labels], 0)
        plot_labels(boxes, cls.squeeze(), names=self.data["names"], save_dir=self.save_dir, on_plot=self.on_plot)
第一次提交 2024-08-14 16:10:21 +08:00			`# Ultralytics YOLO 🚀, AGPL-3.0 license`

			`import math`
			`import random`
			`from copy import copy`

			`import numpy as np`
			`import torch.nn as nn`

			`from ultralytics.data import build_dataloader, build_yolo_dataset`
			`from ultralytics.engine.trainer import BaseTrainer`
			`from ultralytics.models import yolo`
			`from ultralytics.nn.tasks import DetectionModel`
			`from ultralytics.utils import LOGGER, RANK`
			`from ultralytics.utils.plotting import plot_images, plot_labels, plot_results`
			`from ultralytics.utils.torch_utils import de_parallel, torch_distributed_zero_first`


			`class DetectionTrainer(BaseTrainer):`
			`"""`
			`A class extending the BaseTrainer class for training based on a detection model.`

			`Example:`
			```python
			`from ultralytics.models.yolo.detect import DetectionTrainer`

			`args = dict(model='yolov8n.pt', data='coco8.yaml', epochs=3)`
			`trainer = DetectionTrainer(overrides=args)`
			`trainer.train()`
			```
			`"""`

			`def build_dataset(self, img_path, mode="train", batch=None):`
			`"""`
			`Build YOLO Dataset.`

			`Args:`
			`img_path (str): Path to the folder containing images.`
			mode (str): `train` mode or `val` mode, users are able to customize different augmentations for each mode.
			batch (int, optional): Size of batches, this is for `rect`. Defaults to None.
			`"""`
			`gs = max(int(de_parallel(self.model).stride.max() if self.model else 0), 32)`
			`return build_yolo_dataset(self.args, img_path, batch, self.data, mode=mode, rect=mode == "val", stride=gs)`

			`def get_dataloader(self, dataset_path, batch_size=16, rank=0, mode="train"):`
			`"""Construct and return dataloader."""`
			`assert mode in {"train", "val"}, f"Mode must be 'train' or 'val', not {mode}."`
			`with torch_distributed_zero_first(rank): # init dataset *.cache only once if DDP`
			`dataset = self.build_dataset(dataset_path, mode, batch_size)`
			`shuffle = mode == "train"`
			`if getattr(dataset, "rect", False) and shuffle:`
			`LOGGER.warning("WARNING ⚠️ 'rect=True' is incompatible with DataLoader shuffle, setting shuffle=False")`
			`shuffle = False`
			`workers = self.args.workers if mode == "train" else self.args.workers * 2`
			`return build_dataloader(dataset, batch_size, workers, shuffle, rank) # return dataloader`

			`def preprocess_batch(self, batch):`
			`"""Preprocesses a batch of images by scaling and converting to float."""`
			`batch["img"] = batch["img"].to(self.device, non_blocking=True).float() / 255`
			`if self.args.multi_scale:`
			`imgs = batch["img"]`
			`sz = (`
			`random.randrange(self.args.imgsz * 0.5, self.args.imgsz * 1.5 + self.stride)`
			`// self.stride`
			`* self.stride`
			`) # size`
			`sf = sz / max(imgs.shape[2:]) # scale factor`
			`if sf != 1:`
			`ns = [`
			`math.ceil(x * sf / self.stride) * self.stride for x in imgs.shape[2:]`
			`] # new shape (stretched to gs-multiple)`
			`imgs = nn.functional.interpolate(imgs, size=ns, mode="bilinear", align_corners=False)`
			`batch["img"] = imgs`
			`return batch`

			`def set_model_attributes(self):`
			`"""Nl = de_parallel(self.model).model[-1].nl # number of detection layers (to scale hyps)."""`
			`# self.args.box *= 3 / nl # scale to layers`
			`# self.args.cls = self.data["nc"] / 80 3 / nl # scale to classes and layers`
			`# self.args.cls = (self.args.imgsz / 640) * 2 * 3 / nl # scale to image size and layers`
			`self.model.nc = self.data["nc"] # attach number of classes to model`
			`self.model.names = self.data["names"] # attach class names to model`
			`self.model.args = self.args # attach hyperparameters to model`
			`# TODO: self.model.class_weights = labels_to_class_weights(dataset.labels, nc).to(device) * nc`

			`def get_model(self, cfg=None, weights=None, verbose=True):`
			`"""Return a YOLO detection model."""`
			`model = DetectionModel(cfg, nc=self.data["nc"], verbose=verbose and RANK == -1)`
			`if weights:`
			`model.load(weights)`
			`return model`

			`def get_validator(self):`
			`"""Returns a DetectionValidator for YOLO model validation."""`
			`self.loss_names = "box_loss", "cls_loss", "dfl_loss"`
			`return yolo.detect.DetectionValidator(`
			`self.test_loader, save_dir=self.save_dir, args=copy(self.args), _callbacks=self.callbacks`
			`)`

			`def label_loss_items(self, loss_items=None, prefix="train"):`
			`"""`
			`Returns a loss dict with labelled training loss items tensor.`

			`Not needed for classification but necessary for segmentation & detection`
			`"""`
			`keys = [f"{prefix}/{x}" for x in self.loss_names]`
			`if loss_items is not None:`
			`loss_items = [round(float(x), 5) for x in loss_items] # convert tensors to 5 decimal place floats`
			`return dict(zip(keys, loss_items))`
			`else:`
			`return keys`

			`def progress_string(self):`
			`"""Returns a formatted string of training progress with epoch, GPU memory, loss, instances and size."""`
			`return ("\n" + "%11s" * (4 + len(self.loss_names))) % (`
			`"Epoch",`
			`"GPU_mem",`
			`*self.loss_names,`
			`"Instances",`
			`"Size",`
			`)`

			`def plot_training_samples(self, batch, ni):`
			`"""Plots training samples with their annotations."""`
			`plot_images(`
			`images=batch["img"],`
			`batch_idx=batch["batch_idx"],`
			`cls=batch["cls"].squeeze(-1),`
			`bboxes=batch["bboxes"],`
			`paths=batch["im_file"],`
			`fname=self.save_dir / f"train_batch{ni}.jpg",`
			`on_plot=self.on_plot,`
			`)`

			`def plot_metrics(self):`
			`"""Plots metrics from a CSV file."""`
			`plot_results(file=self.csv, on_plot=self.on_plot) # save results.png`

			`def plot_training_labels(self):`
			`"""Create a labeled training plot of the YOLO model."""`
			`boxes = np.concatenate([lb["bboxes"] for lb in self.train_loader.dataset.labels], 0)`
			`cls = np.concatenate([lb["cls"] for lb in self.train_loader.dataset.labels], 0)`
			`plot_labels(boxes, cls.squeeze(), names=self.data["names"], save_dir=self.save_dir, on_plot=self.on_plot)`