# Ultralytics 🚀 AGPL-3.0 License - https://ultralytics.com/license """Model validation metrics.""" from __future__ import annotations import math import warnings from collections import defaultdict from pathlib import Path from typing import Any import numpy as np import torch from ultralytics.utils import LOGGER, DataExportMixin, SimpleClass, TryExcept, checks, plt_settings OKS_SIGMA = ( np.array( [0.26, 0.25, 0.25, 0.35, 0.35, 0.79, 0.79, 0.72, 0.72, 0.62, 0.62, 1.07, 1.07, 0.87, 0.87, 0.89, 0.89], dtype=np.float32, ) / 10.0 ) RLE_WEIGHT = np.array([1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.2, 1.2, 1.5, 1.5, 1.0, 1.0, 1.2, 1.2, 1.5, 1.5]) def bbox_ioa(box1: np.ndarray, box2: np.ndarray, iou: bool = False, eps: float = 1e-7) -> np.ndarray: """Calculate the intersection over box2 area given box1 and box2. Args: box1 (np.ndarray): A numpy array of shape (N, 4) representing N bounding boxes in x1y1x2y2 format. box2 (np.ndarray): A numpy array of shape (M, 4) representing M bounding boxes in x1y1x2y2 format. iou (bool, optional): Calculate the standard IoU if True else return inter_area/box2_area. eps (float, optional): A small value to avoid division by zero. Returns: (np.ndarray): A numpy array of shape (N, M) representing the intersection over box2 area. """ # Get the coordinates of bounding boxes b1_x1, b1_y1, b1_x2, b1_y2 = box1.T b2_x1, b2_y1, b2_x2, b2_y2 = box2.T # Intersection area inter_area = (np.minimum(b1_x2[:, None], b2_x2) - np.maximum(b1_x1[:, None], b2_x1)).clip(0) * ( np.minimum(b1_y2[:, None], b2_y2) - np.maximum(b1_y1[:, None], b2_y1) ).clip(0) # Box2 area area = (b2_x2 - b2_x1) * (b2_y2 - b2_y1) if iou: box1_area = (b1_x2 - b1_x1) * (b1_y2 - b1_y1) area = area + box1_area[:, None] - inter_area # Intersection over box2 area return inter_area / (area + eps) def box_iou(box1: torch.Tensor, box2: torch.Tensor, eps: float = 1e-7) -> torch.Tensor: """Calculate intersection-over-union (IoU) of boxes. Args: box1 (torch.Tensor): A tensor of shape (N, 4) representing N bounding boxes in (x1, y1, x2, y2) format. box2 (torch.Tensor): A tensor of shape (M, 4) representing M bounding boxes in (x1, y1, x2, y2) format. eps (float, optional): A small value to avoid division by zero. Returns: (torch.Tensor): An NxM tensor containing the pairwise IoU values for every element in box1 and box2. References: https://github.com/pytorch/vision/blob/main/torchvision/ops/boxes.py """ # NOTE: Need .float() to get accurate iou values # inter(N,M) = (rb(N,M,2) - lt(N,M,2)).clamp(0).prod(2) (a1, a2), (b1, b2) = box1.float().unsqueeze(1).chunk(2, 2), box2.float().unsqueeze(0).chunk(2, 2) inter = (torch.min(a2, b2) - torch.max(a1, b1)).clamp_(0).prod(2) # IoU = inter / (area1 + area2 - inter) return inter / ((a2 - a1).prod(2) + (b2 - b1).prod(2) - inter + eps) def bbox_iou( box1: torch.Tensor, box2: torch.Tensor, xywh: bool = True, GIoU: bool = False, DIoU: bool = False, CIoU: bool = False, eps: float = 1e-7, ) -> torch.Tensor: """Calculate the Intersection over Union (IoU) between bounding boxes. This function supports various shapes for `box1` and `box2` as long as the last dimension is 4. For instance, you may pass tensors shaped like (4,), (N, 4), (B, N, 4), or (B, N, 1, 4). Internally, the code will split the last dimension into (x, y, w, h) if `xywh=True`, or (x1, y1, x2, y2) if `xywh=False`. Args: box1 (torch.Tensor): A tensor representing one or more bounding boxes, with the last dimension being 4. box2 (torch.Tensor): A tensor representing one or more bounding boxes, with the last dimension being 4. xywh (bool, optional): If True, input boxes are in (x, y, w, h) format. If False, input boxes are in (x1, y1, x2, y2) format. GIoU (bool, optional): If True, calculate Generalized IoU. DIoU (bool, optional): If True, calculate Distance IoU. CIoU (bool, optional): If True, calculate Complete IoU. eps (float, optional): A small value to avoid division by zero. Returns: (torch.Tensor): IoU, GIoU, DIoU, or CIoU values depending on the specified flags. """ # Get the coordinates of bounding boxes if xywh: # transform from xywh to xyxy (x1, y1, w1, h1), (x2, y2, w2, h2) = box1.chunk(4, -1), box2.chunk(4, -1) w1_, h1_, w2_, h2_ = w1 / 2, h1 / 2, w2 / 2, h2 / 2 b1_x1, b1_x2, b1_y1, b1_y2 = x1 - w1_, x1 + w1_, y1 - h1_, y1 + h1_ b2_x1, b2_x2, b2_y1, b2_y2 = x2 - w2_, x2 + w2_, y2 - h2_, y2 + h2_ else: # x1, y1, x2, y2 = box1 b1_x1, b1_y1, b1_x2, b1_y2 = box1.chunk(4, -1) b2_x1, b2_y1, b2_x2, b2_y2 = box2.chunk(4, -1) w1, h1 = b1_x2 - b1_x1, b1_y2 - b1_y1 + eps w2, h2 = b2_x2 - b2_x1, b2_y2 - b2_y1 + eps # Intersection area inter = (b1_x2.minimum(b2_x2) - b1_x1.maximum(b2_x1)).clamp_(0) * ( b1_y2.minimum(b2_y2) - b1_y1.maximum(b2_y1) ).clamp_(0) # Union Area union = w1 * h1 + w2 * h2 - inter + eps # IoU iou = inter / union if CIoU or DIoU or GIoU: cw = b1_x2.maximum(b2_x2) - b1_x1.minimum(b2_x1) # convex (smallest enclosing box) width ch = b1_y2.maximum(b2_y2) - b1_y1.minimum(b2_y1) # convex height if CIoU or DIoU: # Distance or Complete IoU https://arxiv.org/abs/1911.08287v1 c2 = cw.pow(2) + ch.pow(2) + eps # convex diagonal squared rho2 = ( (b2_x1 + b2_x2 - b1_x1 - b1_x2).pow(2) + (b2_y1 + b2_y2 - b1_y1 - b1_y2).pow(2) ) / 4 # center dist**2 if CIoU: # https://github.com/Zzh-tju/DIoU-SSD-pytorch/blob/master/utils/box/box_utils.py#L47 v = (4 / math.pi**2) * ((w2 / h2).atan() - (w1 / h1).atan()).pow(2) with torch.no_grad(): alpha = v / (v - iou + (1 + eps)) return iou - (rho2 / c2 + v * alpha) # CIoU return iou - rho2 / c2 # DIoU c_area = cw * ch + eps # convex area return iou - (c_area - union) / c_area # GIoU https://arxiv.org/pdf/1902.09630.pdf return iou # IoU def mask_iou(mask1: torch.Tensor, mask2: torch.Tensor, eps: float = 1e-7) -> torch.Tensor: """Calculate masks IoU. Args: mask1 (torch.Tensor): A tensor of shape (N, n) where N is the number of ground truth objects and n is the product of image width and height. mask2 (torch.Tensor): A tensor of shape (M, n) where M is the number of predicted objects and n is the product of image width and height. eps (float, optional): A small value to avoid division by zero. Returns: (torch.Tensor): A tensor of shape (N, M) representing masks IoU. """ intersection = torch.matmul(mask1, mask2.T).clamp_(0) union = (mask1.sum(1)[:, None] + mask2.sum(1)[None]) - intersection # (area1 + area2) - intersection return intersection / (union + eps) def kpt_iou( kpt1: torch.Tensor, kpt2: torch.Tensor, area: torch.Tensor, sigma: list[float], eps: float = 1e-7 ) -> torch.Tensor: """Calculate Object Keypoint Similarity (OKS). Args: kpt1 (torch.Tensor): A tensor of shape (N, 17, 3) representing ground truth keypoints. kpt2 (torch.Tensor): A tensor of shape (M, 17, 3) representing predicted keypoints. area (torch.Tensor): A tensor of shape (N,) representing areas from ground truth. sigma (list[float]): A list containing 17 values representing keypoint scales. eps (float, optional): A small value to avoid division by zero. Returns: (torch.Tensor): A tensor of shape (N, M) representing keypoint similarities. """ d = (kpt1[:, None, :, 0] - kpt2[..., 0]).pow(2) + (kpt1[:, None, :, 1] - kpt2[..., 1]).pow(2) # (N, M, 17) sigma = torch.tensor(sigma, device=kpt1.device, dtype=kpt1.dtype) # (17, ) kpt_mask = kpt1[..., 2] != 0 # (N, 17) e = d / ((2 * sigma).pow(2) * (area[:, None, None] + eps) * 2) # from cocoeval # e = d / ((area[None, :, None] + eps) * sigma) ** 2 / 2 # from formula return ((-e).exp() * kpt_mask[:, None]).sum(-1) / (kpt_mask.sum(-1)[:, None] + eps) def _get_covariance_matrix(boxes: torch.Tensor) -> tuple[torch.Tensor, torch.Tensor, torch.Tensor]: """Generate covariance matrix from oriented bounding boxes. Args: boxes (torch.Tensor): A tensor of shape (N, 5) representing rotated bounding boxes, with xywhr format. Returns: (tuple[torch.Tensor, torch.Tensor, torch.Tensor]): Covariance matrix components (a, b, c) where the covariance matrix is [[a, c], [c, b]], each of shape (N, 1). """ # Gaussian bounding boxes, ignore the center points (the first two columns) because they are not needed here. gbbs = torch.cat((boxes[:, 2:4].pow(2) / 12, boxes[:, 4:]), dim=-1) a, b, c = gbbs.split(1, dim=-1) cos = c.cos() sin = c.sin() cos2 = cos.pow(2) sin2 = sin.pow(2) return a * cos2 + b * sin2, a * sin2 + b * cos2, (a - b) * cos * sin def probiou(obb1: torch.Tensor, obb2: torch.Tensor, CIoU: bool = False, eps: float = 1e-7) -> torch.Tensor: """Calculate probabilistic IoU between oriented bounding boxes. Args: obb1 (torch.Tensor): Ground truth OBBs, shape (N, 5), format xywhr. obb2 (torch.Tensor): Predicted OBBs, shape (N, 5), format xywhr. CIoU (bool, optional): If True, calculate CIoU. eps (float, optional): Small value to avoid division by zero. Returns: (torch.Tensor): OBB similarities, shape (N,). Notes: OBB format: [center_x, center_y, width, height, rotation_angle]. References: https://arxiv.org/pdf/2106.06072v1.pdf """ x1, y1 = obb1[..., :2].split(1, dim=-1) x2, y2 = obb2[..., :2].split(1, dim=-1) a1, b1, c1 = _get_covariance_matrix(obb1) a2, b2, c2 = _get_covariance_matrix(obb2) t1 = ( ((a1 + a2) * (y1 - y2).pow(2) + (b1 + b2) * (x1 - x2).pow(2)) / ((a1 + a2) * (b1 + b2) - (c1 + c2).pow(2) + eps) ) * 0.25 t2 = (((c1 + c2) * (x2 - x1) * (y1 - y2)) / ((a1 + a2) * (b1 + b2) - (c1 + c2).pow(2) + eps)) * 0.5 t3 = ( ((a1 + a2) * (b1 + b2) - (c1 + c2).pow(2)) / (4 * ((a1 * b1 - c1.pow(2)).clamp_(0) * (a2 * b2 - c2.pow(2)).clamp_(0)).sqrt() + eps) + eps ).log() * 0.5 bd = (t1 + t2 + t3).clamp(eps, 100.0) hd = (1.0 - (-bd).exp() + eps).sqrt() iou = 1 - hd if CIoU: # only include the wh aspect ratio part w1, h1 = obb1[..., 2:4].split(1, dim=-1) w2, h2 = obb2[..., 2:4].split(1, dim=-1) v = (4 / math.pi**2) * ((w2 / h2).atan() - (w1 / h1).atan()).pow(2) with torch.no_grad(): alpha = v / (v - iou + (1 + eps)) return iou - v * alpha # CIoU return iou def batch_probiou(obb1: torch.Tensor | np.ndarray, obb2: torch.Tensor | np.ndarray, eps: float = 1e-7) -> torch.Tensor: """Calculate the probabilistic IoU between oriented bounding boxes. Args: obb1 (torch.Tensor | np.ndarray): A tensor of shape (N, 5) representing ground truth obbs, with xywhr format. obb2 (torch.Tensor | np.ndarray): A tensor of shape (M, 5) representing predicted obbs, with xywhr format. eps (float, optional): A small value to avoid division by zero. Returns: (torch.Tensor): A tensor of shape (N, M) representing obb similarities. References: https://arxiv.org/pdf/2106.06072v1.pdf """ obb1 = torch.from_numpy(obb1) if isinstance(obb1, np.ndarray) else obb1 obb2 = torch.from_numpy(obb2) if isinstance(obb2, np.ndarray) else obb2 x1, y1 = obb1[..., :2].split(1, dim=-1) x2, y2 = (x.squeeze(-1)[None] for x in obb2[..., :2].split(1, dim=-1)) a1, b1, c1 = _get_covariance_matrix(obb1) a2, b2, c2 = (x.squeeze(-1)[None] for x in _get_covariance_matrix(obb2)) t1 = ( ((a1 + a2) * (y1 - y2).pow(2) + (b1 + b2) * (x1 - x2).pow(2)) / ((a1 + a2) * (b1 + b2) - (c1 + c2).pow(2) + eps) ) * 0.25 t2 = (((c1 + c2) * (x2 - x1) * (y1 - y2)) / ((a1 + a2) * (b1 + b2) - (c1 + c2).pow(2) + eps)) * 0.5 t3 = ( ((a1 + a2) * (b1 + b2) - (c1 + c2).pow(2)) / (4 * ((a1 * b1 - c1.pow(2)).clamp_(0) * (a2 * b2 - c2.pow(2)).clamp_(0)).sqrt() + eps) + eps ).log() * 0.5 bd = (t1 + t2 + t3).clamp(eps, 100.0) hd = (1.0 - (-bd).exp() + eps).sqrt() return 1 - hd def smooth_bce(eps: float = 0.1) -> tuple[float, float]: """Compute smoothed positive and negative Binary Cross-Entropy targets. Args: eps (float, optional): The epsilon value for label smoothing. Returns: pos (float): Positive label smoothing BCE target. neg (float): Negative label smoothing BCE target. References: https://github.com/ultralytics/yolov3/issues/238#issuecomment-598028441 """ return 1.0 - 0.5 * eps, 0.5 * eps class ConfusionMatrix(DataExportMixin): """A class for calculating and updating a confusion matrix for object detection and classification tasks. Attributes: task (str): The type of task, either 'detect' or 'classify'. matrix (np.ndarray): The confusion matrix, with dimensions depending on the task. nc (int): The number of classes. names (dict[int, str]): The names of the classes, used as labels on the plot. matches (dict | None): Contains the indices of ground truths and predictions categorized into TP, FP and FN. """ def __init__(self, names: dict[int, str] = {}, task: str = "detect", save_matches: bool = False): """Initialize a ConfusionMatrix instance. Args: names (dict[int, str], optional): Names of classes, used as labels on the plot. task (str, optional): Type of task, either 'detect' or 'classify'. save_matches (bool, optional): Save the indices of GTs, TPs, FPs, FNs for visualization. """ self.task = task self.nc = len(names) # number of classes self.matrix = np.zeros((self.nc, self.nc)) if self.task == "classify" else np.zeros((self.nc + 1, self.nc + 1)) self.names = names # name of classes self.matches = {} if save_matches else None def _append_matches(self, mtype: str, batch: dict[str, Any], idx: int) -> None: """Append the matches to TP, FP, FN or GT list for the last batch. This method updates the matches dictionary by appending specific batch data to the appropriate match type (True Positive, False Positive, or False Negative). Args: mtype (str): Match type identifier ('TP', 'FP', 'FN' or 'GT'). batch (dict[str, Any]): Batch data containing detection results with keys like 'bboxes', 'cls', 'conf', 'keypoints', 'masks'. idx (int): Index of the specific detection to append from the batch. Notes: For masks, handles both overlap and non-overlap cases. When masks.max() > 1.0, it indicates overlap_mask=True with shape (1, H, W), otherwise uses direct indexing. """ if self.matches is None: return for k, v in batch.items(): if k in {"bboxes", "cls", "conf", "keypoints"}: self.matches[mtype][k] += v[[idx]] elif k == "masks": # NOTE: masks.max() > 1.0 means overlap_mask=True with (1, H, W) shape self.matches[mtype][k] += [v[0] == idx + 1] if v.max() > 1.0 else [v[idx]] def process_cls_preds(self, preds: list[torch.Tensor], targets: list[torch.Tensor]) -> None: """Update confusion matrix for classification task. Args: preds (list[torch.Tensor]): Predicted class labels. targets (list[torch.Tensor]): Ground truth class labels. """ preds, targets = torch.cat(preds)[:, 0], torch.cat(targets) for p, t in zip(preds.cpu().numpy(), targets.cpu().numpy()): self.matrix[p][t] += 1 def process_batch( self, detections: dict[str, torch.Tensor], batch: dict[str, Any], conf: float = 0.25, iou_thres: float = 0.45, ) -> None: """Update confusion matrix for object detection task. Args: detections (dict[str, torch.Tensor]): Dictionary containing detected bounding boxes and their associated information. Should contain 'cls', 'conf', and 'bboxes' keys, where 'bboxes' can be Array[N, 4] for regular boxes or Array[N, 5] for OBB with angle. batch (dict[str, Any]): Batch dictionary containing ground truth data with 'bboxes' (Array[M, 4]| Array[M, 5]) and 'cls' (Array[M]) keys, where M is the number of ground truth objects. conf (float, optional): Confidence threshold for detections. iou_thres (float, optional): IoU threshold for matching detections to ground truth. """ gt_cls, gt_bboxes = batch["cls"], batch["bboxes"] if self.matches is not None: # only if visualization is enabled self.matches = {k: defaultdict(list) for k in {"TP", "FP", "FN", "GT"}} for i in range(gt_cls.shape[0]): self._append_matches("GT", batch, i) # store GT is_obb = gt_bboxes.shape[1] == 5 # check if boxes contains angle for OBB conf = 0.25 if conf in {None, 0.01 if is_obb else 0.001} else conf # apply 0.25 if default val conf is passed no_pred = detections["cls"].shape[0] == 0 if gt_cls.shape[0] == 0: # Check if labels is empty if not no_pred: detections = {k: detections[k][detections["conf"] > conf] for k in detections} detection_classes = detections["cls"].int().tolist() for i, dc in enumerate(detection_classes): self.matrix[dc, self.nc] += 1 # FP self._append_matches("FP", detections, i) return if no_pred: gt_classes = gt_cls.int().tolist() for i, gc in enumerate(gt_classes): self.matrix[self.nc, gc] += 1 # FN self._append_matches("FN", batch, i) return detections = {k: detections[k][detections["conf"] > conf] for k in detections} gt_classes = gt_cls.int().tolist() detection_classes = detections["cls"].int().tolist() bboxes = detections["bboxes"] iou = batch_probiou(gt_bboxes, bboxes) if is_obb else box_iou(gt_bboxes, bboxes) x = torch.where(iou > iou_thres) if x[0].shape[0]: matches = torch.cat((torch.stack(x, 1), iou[x[0], x[1]][:, None]), 1).cpu().numpy() if x[0].shape[0] > 1: matches = matches[matches[:, 2].argsort()[::-1]] matches = matches[np.unique(matches[:, 1], return_index=True)[1]] matches = matches[matches[:, 2].argsort()[::-1]] matches = matches[np.unique(matches[:, 0], return_index=True)[1]] else: matches = np.zeros((0, 3)) n = matches.shape[0] > 0 m0, m1, _ = matches.transpose().astype(int) for i, gc in enumerate(gt_classes): j = m0 == i if n and sum(j) == 1: dc = detection_classes[m1[j].item()] self.matrix[dc, gc] += 1 # TP if class is correct else both an FP and an FN if dc == gc: self._append_matches("TP", detections, m1[j].item()) else: self._append_matches("FP", detections, m1[j].item()) self._append_matches("FN", batch, i) else: self.matrix[self.nc, gc] += 1 # FN self._append_matches("FN", batch, i) for i, dc in enumerate(detection_classes): if not any(m1 == i): self.matrix[dc, self.nc] += 1 # FP self._append_matches("FP", detections, i) def matrix(self): """Return the confusion matrix.""" return self.matrix def tp_fp(self) -> tuple[np.ndarray, np.ndarray]: """Return true positives and false positives. Returns: tp (np.ndarray): True positives. fp (np.ndarray): False positives. """ tp = self.matrix.diagonal() # true positives fp = self.matrix.sum(1) - tp # false positives # fn = self.matrix.sum(0) - tp # false negatives (missed detections) return (tp, fp) if self.task == "classify" else (tp[:-1], fp[:-1]) # remove background class if task=detect def plot_matches(self, img: torch.Tensor, im_file: str, save_dir: Path) -> None: """Plot grid of GT, TP, FP, FN for each image. Args: img (torch.Tensor): Image to plot onto. im_file (str): Image filename to save visualizations. save_dir (Path): Location to save the visualizations to. """ if not self.matches: return from .ops import xyxy2xywh from .plotting import plot_images # Create batch of 4 (GT, TP, FP, FN) labels = defaultdict(list) for i, mtype in enumerate(["GT", "FP", "TP", "FN"]): mbatch = self.matches[mtype] if "conf" not in mbatch: mbatch["conf"] = torch.tensor([1.0] * len(mbatch["bboxes"]), device=img.device) mbatch["batch_idx"] = torch.ones(len(mbatch["bboxes"]), device=img.device) * i for k in mbatch.keys(): labels[k] += mbatch[k] labels = {k: torch.stack(v, 0) if len(v) else torch.empty(0) for k, v in labels.items()} if self.task != "obb" and labels["bboxes"].shape[0]: labels["bboxes"] = xyxy2xywh(labels["bboxes"]) (save_dir / "visualizations").mkdir(parents=True, exist_ok=True) plot_images( labels, img.repeat(4, 1, 1, 1), paths=["Ground Truth", "False Positives", "True Positives", "False Negatives"], fname=save_dir / "visualizations" / Path(im_file).name, names=self.names, max_subplots=4, conf_thres=0.001, ) @TryExcept(msg="ConfusionMatrix plot failure") @plt_settings() def plot(self, normalize: bool = True, save_dir: str = "", on_plot=None): """Plot the confusion matrix using matplotlib and save it to a file. Args: normalize (bool, optional): Whether to normalize the confusion matrix. save_dir (str, optional): Directory where the plot will be saved. on_plot (callable, optional): An optional callback to pass plots path and data when they are rendered. """ import matplotlib.pyplot as plt # scope for faster 'import ultralytics' array = self.matrix / ((self.matrix.sum(0).reshape(1, -1) + 1e-9) if normalize else 1) # normalize columns array[array < 0.005] = np.nan # don't annotate (would appear as 0.00) fig, ax = plt.subplots(1, 1, figsize=(12, 9)) names, n = list(self.names.values()), self.nc if self.nc >= 100: # downsample for large class count k = max(2, self.nc // 60) # step size for downsampling, always > 1 keep_idx = slice(None, None, k) # create slice instead of array names = names[keep_idx] # slice class names array = array[keep_idx, :][:, keep_idx] # slice matrix rows and cols n = (self.nc + k - 1) // k # number of retained classes nc = n if self.task == "classify" else n + 1 # adjust for background if needed ticklabels = "auto" if 0 < nc < 99: ticklabels = names if self.task == "classify" else [*names, "background"] xy_ticks = np.arange(len(ticklabels)) if ticklabels != "auto" else np.arange(nc) tick_fontsize = max(6, 15 - 0.1 * nc) # Minimum size is 6 label_fontsize = max(6, 12 - 0.1 * nc) title_fontsize = max(6, 12 - 0.1 * nc) btm = max(0.1, 0.25 - 0.001 * nc) # Minimum value is 0.1 with warnings.catch_warnings(): warnings.simplefilter("ignore") # suppress empty matrix RuntimeWarning: All-NaN slice encountered im = ax.imshow(array, cmap="Blues", vmin=0.0, interpolation="none") ax.xaxis.set_label_position("bottom") if nc < 30: # Add score for each cell of confusion matrix color_threshold = 0.45 * (1 if normalize else np.nanmax(array)) # text color threshold for i, row in enumerate(array[:nc]): for j, val in enumerate(row[:nc]): val = array[i, j] if np.isnan(val): continue ax.text( j, i, f"{val:.2f}" if normalize else f"{int(val)}", ha="center", va="center", fontsize=10, color="white" if val > color_threshold else "black", ) cbar = fig.colorbar(im, ax=ax, fraction=0.046, pad=0.05) title = "Confusion Matrix" + " Normalized" * normalize ax.set_xlabel("True", fontsize=label_fontsize, labelpad=10) ax.set_ylabel("Predicted", fontsize=label_fontsize, labelpad=10) ax.set_title(title, fontsize=title_fontsize, pad=20) ax.set_xticks(xy_ticks) ax.set_yticks(xy_ticks) ax.tick_params(axis="x", bottom=True, top=False, labelbottom=True, labeltop=False) ax.tick_params(axis="y", left=True, right=False, labelleft=True, labelright=False) if ticklabels != "auto": ax.set_xticklabels(ticklabels, fontsize=tick_fontsize, rotation=90, ha="center") ax.set_yticklabels(ticklabels, fontsize=tick_fontsize) for s in {"left", "right", "bottom", "top", "outline"}: if s != "outline": ax.spines[s].set_visible(False) # Confusion matrix plot don't have outline cbar.ax.spines[s].set_visible(False) fig.subplots_adjust(left=0, right=0.84, top=0.94, bottom=btm) # Adjust layout to ensure equal margins plot_fname = Path(save_dir) / f"{title.lower().replace(' ', '_')}.png" fig.savefig(plot_fname, dpi=250) plt.close(fig) if on_plot: on_plot(plot_fname, {"type": "confusion_matrix", "matrix": self.matrix.tolist()}) def print(self): """Print the confusion matrix to the console.""" for i in range(self.matrix.shape[0]): LOGGER.info(" ".join(map(str, self.matrix[i]))) def summary(self, normalize: bool = False, decimals: int = 5) -> list[dict[str, float]]: """Generate a summarized representation of the confusion matrix as a list of dictionaries, with optional normalization. This is useful for exporting the matrix to various formats such as CSV, XML, HTML, JSON, or SQL. Args: normalize (bool): Whether to normalize the confusion matrix values. decimals (int): Number of decimal places to round the output values to. Returns: (list[dict[str, float]]): A list of dictionaries, each representing one predicted class with corresponding values for all actual classes. Examples: >>> results = model.val(data="coco8.yaml", plots=True) >>> cm_dict = results.confusion_matrix.summary(normalize=True, decimals=5) >>> print(cm_dict) """ import re names = list(self.names.values()) if self.task == "classify" else [*list(self.names.values()), "background"] clean_names, seen = [], set() for name in names: clean_name = re.sub(r"[^a-zA-Z0-9_]", "_", name) original_clean = clean_name counter = 1 while clean_name.lower() in seen: clean_name = f"{original_clean}_{counter}" counter += 1 seen.add(clean_name.lower()) clean_names.append(clean_name) array = (self.matrix / ((self.matrix.sum(0).reshape(1, -1) + 1e-9) if normalize else 1)).round(decimals) return [ dict({"Predicted": clean_names[i]}, **{clean_names[j]: array[i, j] for j in range(len(clean_names))}) for i in range(len(clean_names)) ] def smooth(y: np.ndarray, f: float = 0.05) -> np.ndarray: """Box filter of fraction f.""" nf = round(len(y) * f * 2) // 2 + 1 # number of filter elements (must be odd) p = np.ones(nf // 2) # ones padding yp = np.concatenate((p * y[0], y, p * y[-1]), 0) # y padded return np.convolve(yp, np.ones(nf) / nf, mode="valid") # y-smoothed @plt_settings() def plot_pr_curve( px: np.ndarray, py: np.ndarray, ap: np.ndarray, save_dir: Path = Path("pr_curve.png"), names: dict[int, str] = {}, on_plot=None, ): """Plot precision-recall curve. Args: px (np.ndarray): X values for the PR curve. py (np.ndarray): Y values for the PR curve. ap (np.ndarray): Average precision values. save_dir (Path, optional): Path to save the plot. names (dict[int, str], optional): Dictionary mapping class indices to class names. on_plot (callable, optional): Function to call after plot is saved. """ import matplotlib.pyplot as plt # scope for faster 'import ultralytics' fig, ax = plt.subplots(1, 1, figsize=(9, 6), tight_layout=True) py = np.stack(py, axis=1) if 0 < len(names) < 21: # display per-class legend if < 21 classes for i, y in enumerate(py.T): ax.plot(px, y, linewidth=1, label=f"{names[i]} {ap[i, 0]:.3f}") # plot(recall, precision) else: ax.plot(px, py, linewidth=1, color="gray") # plot(recall, precision) ax.plot(px, py.mean(1), linewidth=3, color="blue", label=f"all classes {ap[:, 0].mean():.3f} mAP@0.5") ax.set_xlabel("Recall") ax.set_ylabel("Precision") ax.set_xlim(0, 1) ax.set_ylim(0, 1) ax.legend(bbox_to_anchor=(1.04, 1), loc="upper left") ax.set_title("Precision-Recall Curve") fig.savefig(save_dir, dpi=250) plt.close(fig) if on_plot: # Pass PR curve data for interactive plotting (class names stored at model level) # Transpose py to match other curves: y[class][point] format on_plot(save_dir, {"type": "pr_curve", "x": px.tolist(), "y": py.T.tolist(), "ap": ap.tolist()}) @plt_settings() def plot_mc_curve( px: np.ndarray, py: np.ndarray, save_dir: Path = Path("mc_curve.png"), names: dict[int, str] = {}, xlabel: str = "Confidence", ylabel: str = "Metric", on_plot=None, ): """Plot metric-confidence curve. Args: px (np.ndarray): X values for the metric-confidence curve. py (np.ndarray): Y values for the metric-confidence curve. save_dir (Path, optional): Path to save the plot. names (dict[int, str], optional): Dictionary mapping class indices to class names. xlabel (str, optional): X-axis label. ylabel (str, optional): Y-axis label. on_plot (callable, optional): Function to call after plot is saved. """ import matplotlib.pyplot as plt # scope for faster 'import ultralytics' fig, ax = plt.subplots(1, 1, figsize=(9, 6), tight_layout=True) if 0 < len(names) < 21: # display per-class legend if < 21 classes for i, y in enumerate(py): ax.plot(px, y, linewidth=1, label=f"{names[i]}") # plot(confidence, metric) else: ax.plot(px, py.T, linewidth=1, color="gray") # plot(confidence, metric) y = smooth(py.mean(0), 0.1) ax.plot(px, y, linewidth=3, color="blue", label=f"all classes {y.max():.2f} at {px[y.argmax()]:.3f}") ax.set_xlabel(xlabel) ax.set_ylabel(ylabel) ax.set_xlim(0, 1) ax.set_ylim(0, 1) ax.legend(bbox_to_anchor=(1.04, 1), loc="upper left") ax.set_title(f"{ylabel}-Confidence Curve") fig.savefig(save_dir, dpi=250) plt.close(fig) if on_plot: # Pass metric-confidence curve data for interactive plotting (class names stored at model level) on_plot(save_dir, {"type": f"{ylabel.lower()}_curve", "x": px.tolist(), "y": py.tolist()}) def compute_ap(recall: list[float], precision: list[float]) -> tuple[float, np.ndarray, np.ndarray]: """Compute the average precision (AP) given the recall and precision curves. Args: recall (list[float]): The recall curve. precision (list[float]): The precision curve. Returns: ap (float): Average precision. mpre (np.ndarray): Precision envelope curve. mrec (np.ndarray): Modified recall curve with sentinel values added at the beginning and end. """ # Append sentinel values to beginning and end mrec = np.concatenate(([0.0], recall, [1.0])) mpre = np.concatenate(([1.0], precision, [0.0])) # Compute the precision envelope mpre = np.flip(np.maximum.accumulate(np.flip(mpre))) # Integrate area under curve method = "interp" # methods: 'continuous', 'interp' if method == "interp": x = np.linspace(0, 1, 101) # 101-point interp (COCO) func = np.trapezoid if checks.check_version(np.__version__, ">=2.0") else np.trapz # np.trapz deprecated ap = func(np.interp(x, mrec, mpre), x) # integrate else: # 'continuous' i = np.where(mrec[1:] != mrec[:-1])[0] # points where x-axis (recall) changes ap = np.sum((mrec[i + 1] - mrec[i]) * mpre[i + 1]) # area under curve return ap, mpre, mrec def ap_per_class( tp: np.ndarray, conf: np.ndarray, pred_cls: np.ndarray, target_cls: np.ndarray, plot: bool = False, on_plot=None, save_dir: Path = Path(), names: dict[int, str] = {}, eps: float = 1e-16, prefix: str = "", ) -> tuple: """Compute the average precision per class for object detection evaluation. Args: tp (np.ndarray): Binary array indicating whether the detection is correct (True) or not (False). conf (np.ndarray): Array of confidence scores of the detections. pred_cls (np.ndarray): Array of predicted classes of the detections. target_cls (np.ndarray): Array of true classes of the targets. plot (bool, optional): Whether to plot PR curves or not. on_plot (callable, optional): A callback to pass plots path and data when they are rendered. save_dir (Path, optional): Directory to save the PR curves. names (dict[int, str], optional): Dictionary of class names to plot PR curves. eps (float, optional): A small value to avoid division by zero. prefix (str, optional): A prefix string for saving the plot files. Returns: tp (np.ndarray): True positive counts at threshold given by max F1 metric for each class. fp (np.ndarray): False positive counts at threshold given by max F1 metric for each class. p (np.ndarray): Precision values at threshold given by max F1 metric for each class. r (np.ndarray): Recall values at threshold given by max F1 metric for each class. f1 (np.ndarray): F1-score values at threshold given by max F1 metric for each class. ap (np.ndarray): Average precision for each class at different IoU thresholds. unique_classes (np.ndarray): An array of unique classes that have data. p_curve (np.ndarray): Precision curves for each class. r_curve (np.ndarray): Recall curves for each class. f1_curve (np.ndarray): F1-score curves for each class. x (np.ndarray): X-axis values for the curves. prec_values (np.ndarray): Precision values at mAP@0.5 for each class. """ # Sort by objectness i = np.argsort(-conf) tp, conf, pred_cls = tp[i], conf[i], pred_cls[i] # Find unique classes unique_classes, nt = np.unique(target_cls, return_counts=True) nc = unique_classes.shape[0] # number of classes, number of detections # Create Precision-Recall curve and compute AP for each class x, prec_values = np.linspace(0, 1, 1000), [] # Average precision, precision and recall curves ap, p_curve, r_curve = np.zeros((nc, tp.shape[1])), np.zeros((nc, 1000)), np.zeros((nc, 1000)) for ci, c in enumerate(unique_classes): i = pred_cls == c n_l = nt[ci] # number of labels n_p = i.sum() # number of predictions if n_p == 0 or n_l == 0: continue # Accumulate FPs and TPs fpc = (1 - tp[i]).cumsum(0) tpc = tp[i].cumsum(0) # Recall recall = tpc / (n_l + eps) # recall curve r_curve[ci] = np.interp(-x, -conf[i], recall[:, 0], left=0) # negative x, xp because xp decreases # Precision precision = tpc / (tpc + fpc) # precision curve p_curve[ci] = np.interp(-x, -conf[i], precision[:, 0], left=1) # p at pr_score # AP from recall-precision curve for j in range(tp.shape[1]): ap[ci, j], mpre, mrec = compute_ap(recall[:, j], precision[:, j]) if j == 0: prec_values.append(np.interp(x, mrec, mpre)) # precision at mAP@0.5 prec_values = np.array(prec_values) if prec_values else np.zeros((1, 1000)) # (nc, 1000) # Compute F1 (harmonic mean of precision and recall) f1_curve = 2 * p_curve * r_curve / (p_curve + r_curve + eps) names = {i: names[k] for i, k in enumerate(unique_classes) if k in names} # dict: only classes that have data if plot: plot_pr_curve(x, prec_values, ap, save_dir / f"{prefix}PR_curve.png", names, on_plot=on_plot) plot_mc_curve(x, f1_curve, save_dir / f"{prefix}F1_curve.png", names, ylabel="F1", on_plot=on_plot) plot_mc_curve(x, p_curve, save_dir / f"{prefix}P_curve.png", names, ylabel="Precision", on_plot=on_plot) plot_mc_curve(x, r_curve, save_dir / f"{prefix}R_curve.png", names, ylabel="Recall", on_plot=on_plot) i = smooth(f1_curve.mean(0), 0.1).argmax() # max F1 index p, r, f1 = p_curve[:, i], r_curve[:, i], f1_curve[:, i] # max-F1 precision, recall, F1 values tp = (r * nt).round() # true positives fp = (tp / (p + eps) - tp).round() # false positives return tp, fp, p, r, f1, ap, unique_classes.astype(int), p_curve, r_curve, f1_curve, x, prec_values class Metric(SimpleClass): """Class for computing evaluation metrics for Ultralytics YOLO models. Attributes: p (list): Precision for each class. Shape: (nc,). r (list): Recall for each class. Shape: (nc,). f1 (list): F1 score for each class. Shape: (nc,). all_ap (list): AP scores for all classes and all IoU thresholds. Shape: (nc, 10). ap_class_index (list): Index of class for each AP score. Shape: (nc,). nc (int): Number of classes. Methods: ap50: AP at IoU threshold of 0.5 for all classes. ap: AP at IoU thresholds from 0.5 to 0.95 for all classes. mp: Mean precision of all classes. mr: Mean recall of all classes. map50: Mean AP at IoU threshold of 0.5 for all classes. map75: Mean AP at IoU threshold of 0.75 for all classes. map: Mean AP at IoU thresholds from 0.5 to 0.95 for all classes. mean_results: Mean of results, returns mp, mr, map50, map. class_result: Class-aware result, returns p[i], r[i], ap50[i], ap[i]. maps: mAP of each class. fitness: Model fitness as a weighted combination of metrics. update: Update metric attributes with new evaluation results. curves: Provides a list of curves for accessing specific metrics like precision, recall, F1, etc. curves_results: Provide a list of results for accessing specific metrics like precision, recall, F1, etc. """ def __init__(self) -> None: """Initialize a Metric instance for computing evaluation metrics for the YOLO model.""" self.p = [] # (nc, ) self.r = [] # (nc, ) self.f1 = [] # (nc, ) self.all_ap = [] # (nc, 10) self.ap_class_index = [] # (nc, ) self.nc = 0 @property def ap50(self) -> np.ndarray | list: """Return the Average Precision (AP) at an IoU threshold of 0.5 for all classes. Returns: (np.ndarray | list): Array of shape (nc,) with AP50 values per class, or an empty list if not available. """ return self.all_ap[:, 0] if len(self.all_ap) else [] @property def ap(self) -> np.ndarray | list: """Return the Average Precision (AP) at an IoU threshold of 0.5-0.95 for all classes. Returns: (np.ndarray | list): Array of shape (nc,) with AP50-95 values per class, or an empty list if not available. """ return self.all_ap.mean(1) if len(self.all_ap) else [] @property def mp(self) -> float: """Return the Mean Precision of all classes. Returns: (float): The mean precision of all classes. """ return self.p.mean() if len(self.p) else 0.0 @property def mr(self) -> float: """Return the Mean Recall of all classes. Returns: (float): The mean recall of all classes. """ return self.r.mean() if len(self.r) else 0.0 @property def map50(self) -> float: """Return the mean Average Precision (mAP) at an IoU threshold of 0.5. Returns: (float): The mAP at an IoU threshold of 0.5. """ return self.all_ap[:, 0].mean() if len(self.all_ap) else 0.0 @property def map75(self) -> float: """Return the mean Average Precision (mAP) at an IoU threshold of 0.75. Returns: (float): The mAP at an IoU threshold of 0.75. """ return self.all_ap[:, 5].mean() if len(self.all_ap) else 0.0 @property def map(self) -> float: """Return the mean Average Precision (mAP) over IoU thresholds of 0.5 - 0.95 in steps of 0.05. Returns: (float): The mAP over IoU thresholds of 0.5 - 0.95 in steps of 0.05. """ return self.all_ap.mean() if len(self.all_ap) else 0.0 def mean_results(self) -> list[float]: """Return mean of results, mp, mr, map50, map.""" return [self.mp, self.mr, self.map50, self.map] def class_result(self, i: int) -> tuple[float, float, float, float]: """Return class-aware result, p[i], r[i], ap50[i], ap[i].""" return self.p[i], self.r[i], self.ap50[i], self.ap[i] @property def maps(self) -> np.ndarray: """Return mAP of each class.""" maps = np.zeros(self.nc) + self.map for i, c in enumerate(self.ap_class_index): maps[c] = self.ap[i] return maps def fitness(self) -> float: """Return model fitness as a weighted combination of metrics.""" w = [0.0, 0.0, 0.0, 1.0] # weights for [P, R, mAP@0.5, mAP@0.5:0.95] return float((np.nan_to_num(np.array(self.mean_results())) * w).sum()) def update(self, results: tuple): """Update the evaluation metrics with a new set of results. Args: results (tuple): A tuple containing evaluation metrics: - p (list): Precision for each class. - r (list): Recall for each class. - f1 (list): F1 score for each class. - all_ap (list): AP scores for all classes and all IoU thresholds. - ap_class_index (list): Index of class for each AP score. - p_curve (list): Precision curve for each class. - r_curve (list): Recall curve for each class. - f1_curve (list): F1 curve for each class. - px (list): X values for the curves. - prec_values (list): Precision values for each class. """ ( self.p, self.r, self.f1, self.all_ap, self.ap_class_index, self.p_curve, self.r_curve, self.f1_curve, self.px, self.prec_values, ) = results @property def curves(self) -> list: """Return a list of curves for accessing specific metrics curves.""" return [] @property def curves_results(self) -> list[list]: """Return a list of curves results for accessing specific metrics curves.""" return [ [self.px, self.prec_values, "Recall", "Precision"], [self.px, self.f1_curve, "Confidence", "F1"], [self.px, self.p_curve, "Confidence", "Precision"], [self.px, self.r_curve, "Confidence", "Recall"], ] class DetMetrics(SimpleClass, DataExportMixin): """Utility class for computing detection metrics such as precision, recall, and mean average precision (mAP). Attributes: names (dict[int, str]): A dictionary of class names. box (Metric): An instance of the Metric class for storing detection results. speed (dict[str, float]): A dictionary for storing execution times of different parts of the detection process. stats (dict[str, list]): A dictionary containing lists for true positives, confidence scores, predicted classes, target classes, and target images. nt_per_class: Number of targets per class. nt_per_image: Number of targets per image. Methods: update_stats: Update statistics by appending new values to existing stat collections. process: Process predicted results for object detection and update metrics. clear_stats: Clear the stored statistics. keys: Return a list of keys for accessing specific metrics. mean_results: Calculate mean of detected objects & return precision, recall, mAP50, and mAP50-95. class_result: Return the result of evaluating the performance of an object detection model on a specific class. maps: Return mean Average Precision (mAP) scores per class. fitness: Return the fitness of box object. ap_class_index: Return the average precision index per class. results_dict: Return dictionary of computed performance metrics and statistics. curves: Return a list of curves for accessing specific metrics curves. curves_results: Return a list of computed performance metrics and statistics. summary: Generate a summarized representation of per-class detection metrics as a list of dictionaries. """ def __init__(self, names: dict[int, str] = {}) -> None: """Initialize a DetMetrics instance with class names. Args: names (dict[int, str], optional): Dictionary of class names. """ self.names = names self.box = Metric() self.speed = {"preprocess": 0.0, "inference": 0.0, "loss": 0.0, "postprocess": 0.0} self.stats = dict(tp=[], conf=[], pred_cls=[], target_cls=[], target_img=[]) self.nt_per_class = None self.nt_per_image = None def update_stats(self, stat: dict[str, Any]) -> None: """Update statistics by appending new values to existing stat collections. Args: stat (dict[str, Any]): Dictionary containing new statistical values to append. Keys should match existing keys in self.stats. """ for k in self.stats.keys(): self.stats[k].append(stat[k]) def process(self, save_dir: Path = Path("."), plot: bool = False, on_plot=None) -> dict[str, np.ndarray]: """Process predicted results for object detection and update metrics. Args: save_dir (Path): Directory to save plots. Defaults to Path("."). plot (bool): Whether to plot precision-recall curves. Defaults to False. on_plot (callable, optional): Function to call after plots are generated. Defaults to None. Returns: (dict[str, np.ndarray]): Dictionary containing concatenated statistics arrays. """ stats = {k: np.concatenate(v, 0) for k, v in self.stats.items()} # to numpy if not stats: return stats results = ap_per_class( stats["tp"], stats["conf"], stats["pred_cls"], stats["target_cls"], plot=plot, save_dir=save_dir, names=self.names, on_plot=on_plot, prefix="Box", )[2:] self.box.nc = len(self.names) self.box.update(results) self.nt_per_class = np.bincount(stats["target_cls"].astype(int), minlength=len(self.names)) self.nt_per_image = np.bincount(stats["target_img"].astype(int), minlength=len(self.names)) return stats def clear_stats(self): """Clear the stored statistics.""" for v in self.stats.values(): v.clear() @property def keys(self) -> list[str]: """Return a list of keys for accessing specific metrics.""" return ["metrics/precision(B)", "metrics/recall(B)", "metrics/mAP50(B)", "metrics/mAP50-95(B)"] def mean_results(self) -> list[float]: """Calculate mean of detected objects & return precision, recall, mAP50, and mAP50-95.""" return self.box.mean_results() def class_result(self, i: int) -> tuple[float, float, float, float]: """Return the result of evaluating the performance of an object detection model on a specific class.""" return self.box.class_result(i) @property def maps(self) -> np.ndarray: """Return mean Average Precision (mAP) scores per class.""" return self.box.maps @property def fitness(self) -> float: """Return the fitness of box object.""" return self.box.fitness() @property def ap_class_index(self) -> list: """Return the average precision index per class.""" return self.box.ap_class_index @property def results_dict(self) -> dict[str, float]: """Return dictionary of computed performance metrics and statistics.""" keys = [*self.keys, "fitness"] values = ((float(x) if hasattr(x, "item") else x) for x in ([*self.mean_results(), self.fitness])) return dict(zip(keys, values)) @property def curves(self) -> list[str]: """Return a list of curves for accessing specific metrics curves.""" return ["Precision-Recall(B)", "F1-Confidence(B)", "Precision-Confidence(B)", "Recall-Confidence(B)"] @property def curves_results(self) -> list[list]: """Return a list of computed performance metrics and statistics.""" return self.box.curves_results def summary(self, normalize: bool = True, decimals: int = 5) -> list[dict[str, Any]]: """Generate a summarized representation of per-class detection metrics as a list of dictionaries. Includes shared scalar metrics (mAP, mAP50, mAP75) alongside precision, recall, and F1-score for each class. Args: normalize (bool): For Detect metrics, everything is normalized by default [0-1]. decimals (int): Number of decimal places to round the metrics values to. Returns: (list[dict[str, Any]]): A list of dictionaries, each representing one class with corresponding metric values. Examples: >>> results = model.val(data="coco8.yaml") >>> detection_summary = results.summary() >>> print(detection_summary) """ per_class = { "Box-P": self.box.p, "Box-R": self.box.r, "Box-F1": self.box.f1, } return [ { "Class": self.names[self.ap_class_index[i]], "Images": self.nt_per_image[self.ap_class_index[i]], "Instances": self.nt_per_class[self.ap_class_index[i]], **{k: round(v[i], decimals) for k, v in per_class.items()}, "mAP50": round(self.class_result(i)[2], decimals), "mAP50-95": round(self.class_result(i)[3], decimals), } for i in range(len(per_class["Box-P"])) ] class SegmentMetrics(DetMetrics): """Calculate and aggregate detection and segmentation metrics over a given set of classes. Attributes: names (dict[int, str]): Dictionary of class names. box (Metric): An instance of the Metric class for storing detection results. seg (Metric): An instance of the Metric class to calculate mask segmentation metrics. speed (dict[str, float]): A dictionary for storing execution times of different parts of the detection process. stats (dict[str, list]): A dictionary containing lists for true positives, confidence scores, predicted classes, target classes, and target images. nt_per_class: Number of targets per class. nt_per_image: Number of targets per image. Methods: process: Process the detection and segmentation metrics over the given set of predictions. keys: Return a list of keys for accessing metrics. mean_results: Return the mean metrics for bounding box and segmentation results. class_result: Return classification results for a specified class index. maps: Return mAP scores for object detection and segmentation models. fitness: Return the fitness score for both segmentation and bounding box models. curves: Return a list of curves for accessing specific metrics curves. curves_results: Provide a list of computed performance metrics and statistics. summary: Generate a summarized representation of per-class segmentation metrics as a list of dictionaries. """ def __init__(self, names: dict[int, str] = {}) -> None: """Initialize a SegmentMetrics instance with class names. Args: names (dict[int, str], optional): Dictionary of class names. """ DetMetrics.__init__(self, names) self.seg = Metric() self.stats["tp_m"] = [] # add additional stats for masks def process(self, save_dir: Path = Path("."), plot: bool = False, on_plot=None) -> dict[str, np.ndarray]: """Process the detection and segmentation metrics over the given set of predictions. Args: save_dir (Path): Directory to save plots. Defaults to Path("."). plot (bool): Whether to plot precision-recall curves. Defaults to False. on_plot (callable, optional): Function to call after plots are generated. Defaults to None. Returns: (dict[str, np.ndarray]): Dictionary containing concatenated statistics arrays. """ stats = DetMetrics.process(self, save_dir, plot, on_plot=on_plot) # process box stats results_mask = ap_per_class( stats["tp_m"], stats["conf"], stats["pred_cls"], stats["target_cls"], plot=plot, on_plot=on_plot, save_dir=save_dir, names=self.names, prefix="Mask", )[2:] self.seg.nc = len(self.names) self.seg.update(results_mask) return stats @property def keys(self) -> list[str]: """Return a list of keys for accessing metrics.""" return [ *DetMetrics.keys.fget(self), "metrics/precision(M)", "metrics/recall(M)", "metrics/mAP50(M)", "metrics/mAP50-95(M)", ] def mean_results(self) -> list[float]: """Return the mean metrics for bounding box and segmentation results.""" return DetMetrics.mean_results(self) + self.seg.mean_results() def class_result(self, i: int) -> list[float]: """Return classification results for a specified class index.""" return DetMetrics.class_result(self, i) + self.seg.class_result(i) @property def maps(self) -> np.ndarray: """Return mAP scores for object detection and segmentation models.""" return DetMetrics.maps.fget(self) + self.seg.maps @property def fitness(self) -> float: """Return the fitness score for both segmentation and bounding box models.""" return self.seg.fitness() + DetMetrics.fitness.fget(self) @property def curves(self) -> list[str]: """Return a list of curves for accessing specific metrics curves.""" return [ *DetMetrics.curves.fget(self), "Precision-Recall(M)", "F1-Confidence(M)", "Precision-Confidence(M)", "Recall-Confidence(M)", ] @property def curves_results(self) -> list[list]: """Return a list of computed performance metrics and statistics.""" return DetMetrics.curves_results.fget(self) + self.seg.curves_results def summary(self, normalize: bool = True, decimals: int = 5) -> list[dict[str, Any]]: """Generate a summarized representation of per-class segmentation metrics as a list of dictionaries. Includes both box and mask scalar metrics (mAP, mAP50, mAP75) alongside precision, recall, and F1-score for each class. Args: normalize (bool): For Segment metrics, everything is normalized by default [0-1]. decimals (int): Number of decimal places to round the metrics values to. Returns: (list[dict[str, Any]]): A list of dictionaries, each representing one class with corresponding metric values. Examples: >>> results = model.val(data="coco8-seg.yaml") >>> seg_summary = results.summary(decimals=4) >>> print(seg_summary) """ per_class = { "Mask-P": self.seg.p, "Mask-R": self.seg.r, "Mask-F1": self.seg.f1, } summary = DetMetrics.summary(self, normalize, decimals) # get box summary for i, s in enumerate(summary): s.update({**{k: round(v[i], decimals) for k, v in per_class.items()}}) return summary class PoseMetrics(DetMetrics): """Calculate and aggregate detection and pose metrics over a given set of classes. Attributes: names (dict[int, str]): Dictionary of class names. pose (Metric): An instance of the Metric class to calculate pose metrics. box (Metric): An instance of the Metric class for storing detection results. speed (dict[str, float]): A dictionary for storing execution times of different parts of the detection process. stats (dict[str, list]): A dictionary containing lists for true positives, confidence scores, predicted classes, target classes, and target images. nt_per_class: Number of targets per class. nt_per_image: Number of targets per image. Methods: process: Process the detection and pose metrics over the given set of predictions. keys: Return a list of keys for accessing metrics. mean_results: Return the mean results of box and pose. class_result: Return the class-wise detection results for a specific class i. maps: Return the mean average precision (mAP) per class for both box and pose detections. fitness: Return combined fitness score for pose and box detection. curves: Return a list of curves for accessing specific metrics curves. curves_results: Provide a list of computed performance metrics and statistics. summary: Generate a summarized representation of per-class pose metrics as a list of dictionaries. """ def __init__(self, names: dict[int, str] = {}) -> None: """Initialize the PoseMetrics class with class names. Args: names (dict[int, str], optional): Dictionary of class names. """ super().__init__(names) self.pose = Metric() self.stats["tp_p"] = [] # add additional stats for pose def process(self, save_dir: Path = Path("."), plot: bool = False, on_plot=None) -> dict[str, np.ndarray]: """Process the detection and pose metrics over the given set of predictions. Args: save_dir (Path): Directory to save plots. Defaults to Path("."). plot (bool): Whether to plot precision-recall curves. Defaults to False. on_plot (callable, optional): Function to call after plots are generated. Returns: (dict[str, np.ndarray]): Dictionary containing concatenated statistics arrays. """ stats = DetMetrics.process(self, save_dir, plot, on_plot=on_plot) # process box stats results_pose = ap_per_class( stats["tp_p"], stats["conf"], stats["pred_cls"], stats["target_cls"], plot=plot, on_plot=on_plot, save_dir=save_dir, names=self.names, prefix="Pose", )[2:] self.pose.nc = len(self.names) self.pose.update(results_pose) return stats @property def keys(self) -> list[str]: """Return a list of evaluation metric keys.""" return [ *DetMetrics.keys.fget(self), "metrics/precision(P)", "metrics/recall(P)", "metrics/mAP50(P)", "metrics/mAP50-95(P)", ] def mean_results(self) -> list[float]: """Return the mean results of box and pose.""" return DetMetrics.mean_results(self) + self.pose.mean_results() def class_result(self, i: int) -> list[float]: """Return the class-wise detection results for a specific class i.""" return DetMetrics.class_result(self, i) + self.pose.class_result(i) @property def maps(self) -> np.ndarray: """Return the mean average precision (mAP) per class for both box and pose detections.""" return DetMetrics.maps.fget(self) + self.pose.maps @property def fitness(self) -> float: """Return combined fitness score for pose and box detection.""" return self.pose.fitness() + DetMetrics.fitness.fget(self) @property def curves(self) -> list[str]: """Return a list of curves for accessing specific metrics curves.""" return [ *DetMetrics.curves.fget(self), "Precision-Recall(B)", "F1-Confidence(B)", "Precision-Confidence(B)", "Recall-Confidence(B)", "Precision-Recall(P)", "F1-Confidence(P)", "Precision-Confidence(P)", "Recall-Confidence(P)", ] @property def curves_results(self) -> list[list]: """Return a list of computed performance metrics and statistics.""" return DetMetrics.curves_results.fget(self) + self.pose.curves_results def summary(self, normalize: bool = True, decimals: int = 5) -> list[dict[str, Any]]: """Generate a summarized representation of per-class pose metrics as a list of dictionaries. Includes both box and pose scalar metrics (mAP, mAP50, mAP75) alongside precision, recall, and F1-score for each class. Args: normalize (bool): For Pose metrics, everything is normalized by default [0-1]. decimals (int): Number of decimal places to round the metrics values to. Returns: (list[dict[str, Any]]): A list of dictionaries, each representing one class with corresponding metric values. Examples: >>> results = model.val(data="coco8-pose.yaml") >>> pose_summary = results.summary(decimals=4) >>> print(pose_summary) """ per_class = { "Pose-P": self.pose.p, "Pose-R": self.pose.r, "Pose-F1": self.pose.f1, } summary = DetMetrics.summary(self, normalize, decimals) # get box summary for i, s in enumerate(summary): s.update({**{k: round(v[i], decimals) for k, v in per_class.items()}}) return summary class ClassifyMetrics(SimpleClass, DataExportMixin): """Class for computing classification metrics including top-1 and top-5 accuracy. Attributes: top1 (float): The top-1 accuracy. top5 (float): The top-5 accuracy. speed (dict[str, float]): A dictionary containing the time taken for each step in the pipeline. Methods: process: Process target classes and predicted classes to compute metrics. fitness: Return mean of top-1 and top-5 accuracies as fitness score. results_dict: Return a dictionary with model's performance metrics and fitness score. keys: Return a list of keys for the results_dict property. curves: Return a list of curves for accessing specific metrics curves. curves_results: Provide a list of computed performance metrics and statistics. summary: Generate a single-row summary of classification metrics (Top-1 and Top-5 accuracy). """ def __init__(self) -> None: """Initialize a ClassifyMetrics instance.""" self.top1 = 0 self.top5 = 0 self.speed = {"preprocess": 0.0, "inference": 0.0, "loss": 0.0, "postprocess": 0.0} def process(self, targets: torch.Tensor, pred: torch.Tensor): """Process target classes and predicted classes to compute metrics. Args: targets (torch.Tensor): Target classes. pred (torch.Tensor): Predicted classes. """ pred, targets = torch.cat(pred), torch.cat(targets) correct = (targets[:, None] == pred).float() acc = torch.stack((correct[:, 0], correct.max(1).values), dim=1) # (top1, top5) accuracy self.top1, self.top5 = acc.mean(0).tolist() @property def fitness(self) -> float: """Return mean of top-1 and top-5 accuracies as fitness score.""" return (self.top1 + self.top5) / 2 @property def results_dict(self) -> dict[str, float]: """Return a dictionary with model's performance metrics and fitness score.""" return dict(zip([*self.keys, "fitness"], [self.top1, self.top5, self.fitness])) @property def keys(self) -> list[str]: """Return a list of keys for the results_dict property.""" return ["metrics/accuracy_top1", "metrics/accuracy_top5"] @property def curves(self) -> list: """Return a list of curves for accessing specific metrics curves.""" return [] @property def curves_results(self) -> list: """Return a list of curves results for accessing specific metrics curves.""" return [] def summary(self, normalize: bool = True, decimals: int = 5) -> list[dict[str, float]]: """Generate a single-row summary of classification metrics (Top-1 and Top-5 accuracy). Args: normalize (bool): For Classify metrics, everything is normalized by default [0-1]. decimals (int): Number of decimal places to round the metrics values to. Returns: (list[dict[str, float]]): A list with one dictionary containing Top-1 and Top-5 classification accuracy. Examples: >>> results = model.val(data="imagenet10") >>> classify_summary = results.summary(decimals=4) >>> print(classify_summary) """ return [{"top1_acc": round(self.top1, decimals), "top5_acc": round(self.top5, decimals)}] class OBBMetrics(DetMetrics): """Metrics for evaluating oriented bounding box (OBB) detection. Attributes: names (dict[int, str]): Dictionary of class names. box (Metric): An instance of the Metric class for storing detection results. speed (dict[str, float]): A dictionary for storing execution times of different parts of the detection process. stats (dict[str, list]): A dictionary containing lists for true positives, confidence scores, predicted classes, target classes, and target images. nt_per_class: Number of targets per class. nt_per_image: Number of targets per image. References: https://arxiv.org/pdf/2106.06072.pdf """ def __init__(self, names: dict[int, str] = {}) -> None: """Initialize an OBBMetrics instance with class names. Args: names (dict[int, str], optional): Dictionary of class names. """ DetMetrics.__init__(self, names)