# Ultralytics YOLO 🚀, AGPL-3.0 license import contextlib import math import warnings from pathlib import Path import cv2 import matplotlib.pyplot as plt import numpy as np import torch from PIL import Image, ImageDraw, ImageFont from PIL import __version__ as pil_version from ultralytics.utils import LOGGER, TryExcept, ops, plt_settings, threaded from .checks import check_font, check_version, is_ascii from .files import increment_path class Colors: """ Ultralytics default color palette https://ultralytics.com/. This class provides methods to work with the Ultralytics color palette, including converting hex color codes to RGB values. Attributes: palette (list of tuple): List of RGB color values. n (int): The number of colors in the palette. pose_palette (np.ndarray): A specific color palette array with dtype np.uint8. """ def __init__(self): """Initialize colors as hex = matplotlib.colors.TABLEAU_COLORS.values().""" hexs = ( "FF3838", "FF9D97", "FF701F", "FFB21D", "CFD231", "48F90A", "92CC17", "3DDB86", "1A9334", "00D4BB", "2C99A8", "00C2FF", "344593", "6473FF", "0018EC", "8438FF", "520085", "CB38FF", "FF95C8", "FF37C7", ) self.palette = [self.hex2rgb(f"#{c}") for c in hexs] self.n = len(self.palette) self.pose_palette = np.array( [ [255, 128, 0], [255, 153, 51], [255, 178, 102], [230, 230, 0], [255, 153, 255], [153, 204, 255], [255, 102, 255], [255, 51, 255], [102, 178, 255], [51, 153, 255], [255, 153, 153], [255, 102, 102], [255, 51, 51], [153, 255, 153], [102, 255, 102], [51, 255, 51], [0, 255, 0], [0, 0, 255], [255, 0, 0], [255, 255, 255], ], dtype=np.uint8, ) def __call__(self, i, bgr=False): """Converts hex color codes to RGB values.""" c = self.palette[int(i) % self.n] return (c[2], c[1], c[0]) if bgr else c @staticmethod def hex2rgb(h): """Converts hex color codes to RGB values (i.e. default PIL order).""" return tuple(int(h[1 + i : 1 + i + 2], 16) for i in (0, 2, 4)) colors = Colors() # create instance for 'from utils.plots import colors' class Annotator: """ Ultralytics Annotator for train/val mosaics and JPGs and predictions annotations. Attributes: im (Image.Image or numpy array): The image to annotate. pil (bool): Whether to use PIL or cv2 for drawing annotations. font (ImageFont.truetype or ImageFont.load_default): Font used for text annotations. lw (float): Line width for drawing. skeleton (List[List[int]]): Skeleton structure for keypoints. limb_color (List[int]): Color palette for limbs. kpt_color (List[int]): Color palette for keypoints. """ def __init__(self, im, line_width=None, font_size=None, font="Arial.ttf", pil=False, example="abc"): """Initialize the Annotator class with image and line width along with color palette for keypoints and limbs.""" non_ascii = not is_ascii(example) # non-latin labels, i.e. asian, arabic, cyrillic input_is_pil = isinstance(im, Image.Image) self.pil = pil or non_ascii or input_is_pil self.lw = line_width or max(round(sum(im.size if input_is_pil else im.shape) / 2 * 0.003), 2) if self.pil: # use PIL self.im = im if input_is_pil else Image.fromarray(im) self.draw = ImageDraw.Draw(self.im) try: font = check_font("Arial.Unicode.ttf" if non_ascii else font) size = font_size or max(round(sum(self.im.size) / 2 * 0.035), 12) self.font = ImageFont.truetype(str(font), size) except Exception: self.font = ImageFont.load_default() # Deprecation fix for w, h = getsize(string) -> _, _, w, h = getbox(string) if check_version(pil_version, "9.2.0"): self.font.getsize = lambda x: self.font.getbbox(x)[2:4] # text width, height else: # use cv2 assert im.data.contiguous, "Image not contiguous. Apply np.ascontiguousarray(im) to Annotator input images." self.im = im if im.flags.writeable else im.copy() self.tf = max(self.lw - 1, 1) # font thickness self.sf = self.lw / 3 # font scale # Pose self.skeleton = [ [16, 14], [14, 12], [17, 15], [15, 13], [12, 13], [6, 12], [7, 13], [6, 7], [6, 8], [7, 9], [8, 10], [9, 11], [2, 3], [1, 2], [1, 3], [2, 4], [3, 5], [4, 6], [5, 7], ] self.limb_color = colors.pose_palette[[9, 9, 9, 9, 7, 7, 7, 0, 0, 0, 0, 0, 16, 16, 16, 16, 16, 16, 16]] self.kpt_color = colors.pose_palette[[16, 16, 16, 16, 16, 0, 0, 0, 0, 0, 0, 9, 9, 9, 9, 9, 9]] def box_label(self, box, label="", color=(128, 128, 128), txt_color=(255, 255, 255), rotated=False): """Add one xyxy box to image with label.""" if isinstance(box, torch.Tensor): box = box.tolist() if self.pil or not is_ascii(label): if rotated: p1 = box[0] # NOTE: PIL-version polygon needs tuple type. self.draw.polygon([tuple(b) for b in box], width=self.lw, outline=color) else: p1 = (box[0], box[1]) self.draw.rectangle(box, width=self.lw, outline=color) # box if label: w, h = self.font.getsize(label) # text width, height outside = p1[1] - h >= 0 # label fits outside box self.draw.rectangle( (p1[0], p1[1] - h if outside else p1[1], p1[0] + w + 1, p1[1] + 1 if outside else p1[1] + h + 1), fill=color, ) # self.draw.text((box[0], box[1]), label, fill=txt_color, font=self.font, anchor='ls') # for PIL>8.0 self.draw.text((p1[0], p1[1] - h if outside else p1[1]), label, fill=txt_color, font=self.font) else: # cv2 if rotated: p1 = [int(b) for b in box[0]] # NOTE: cv2-version polylines needs np.asarray type. cv2.polylines(self.im, [np.asarray(box, dtype=int)], True, color, self.lw) else: p1, p2 = (int(box[0]), int(box[1])), (int(box[2]), int(box[3])) cv2.rectangle(self.im, p1, p2, color, thickness=self.lw, lineType=cv2.LINE_AA) if label: w, h = cv2.getTextSize(label, 0, fontScale=self.sf, thickness=self.tf)[0] # text width, height outside = p1[1] - h >= 3 p2 = p1[0] + w, p1[1] - h - 3 if outside else p1[1] + h + 3 cv2.rectangle(self.im, p1, p2, color, -1, cv2.LINE_AA) # filled cv2.putText( self.im, label, (p1[0], p1[1] - 2 if outside else p1[1] + h + 2), 0, self.sf, txt_color, thickness=self.tf, lineType=cv2.LINE_AA, ) def masks(self, masks, colors, im_gpu, alpha=0.5, retina_masks=False): """ Plot masks on image. Args: masks (tensor): Predicted masks on cuda, shape: [n, h, w] colors (List[List[Int]]): Colors for predicted masks, [[r, g, b] * n] im_gpu (tensor): Image is in cuda, shape: [3, h, w], range: [0, 1] alpha (float): Mask transparency: 0.0 fully transparent, 1.0 opaque retina_masks (bool): Whether to use high resolution masks or not. Defaults to False. """ if self.pil: # Convert to numpy first self.im = np.asarray(self.im).copy() if len(masks) == 0: self.im[:] = im_gpu.permute(1, 2, 0).contiguous().cpu().numpy() * 255 if im_gpu.device != masks.device: im_gpu = im_gpu.to(masks.device) colors = torch.tensor(colors, device=masks.device, dtype=torch.float32) / 255.0 # shape(n,3) colors = colors[:, None, None] # shape(n,1,1,3) masks = masks.unsqueeze(3) # shape(n,h,w,1) masks_color = masks * (colors * alpha) # shape(n,h,w,3) inv_alpha_masks = (1 - masks * alpha).cumprod(0) # shape(n,h,w,1) mcs = masks_color.max(dim=0).values # shape(n,h,w,3) im_gpu = im_gpu.flip(dims=[0]) # flip channel im_gpu = im_gpu.permute(1, 2, 0).contiguous() # shape(h,w,3) im_gpu = im_gpu * inv_alpha_masks[-1] + mcs im_mask = im_gpu * 255 im_mask_np = im_mask.byte().cpu().numpy() self.im[:] = im_mask_np if retina_masks else ops.scale_image(im_mask_np, self.im.shape) if self.pil: # Convert im back to PIL and update draw self.fromarray(self.im) def kpts(self, kpts, shape=(640, 640), radius=5, kpt_line=True): """ Plot keypoints on the image. Args: kpts (tensor): Predicted keypoints with shape [17, 3]. Each keypoint has (x, y, confidence). shape (tuple): Image shape as a tuple (h, w), where h is the height and w is the width. radius (int, optional): Radius of the drawn keypoints. Default is 5. kpt_line (bool, optional): If True, the function will draw lines connecting keypoints for human pose. Default is True. Note: `kpt_line=True` currently only supports human pose plotting. """ if self.pil: # Convert to numpy first self.im = np.asarray(self.im).copy() nkpt, ndim = kpts.shape is_pose = nkpt == 17 and ndim in {2, 3} kpt_line &= is_pose # `kpt_line=True` for now only supports human pose plotting for i, k in enumerate(kpts): color_k = [int(x) for x in self.kpt_color[i]] if is_pose else colors(i) x_coord, y_coord = k[0], k[1] if x_coord % shape[1] != 0 and y_coord % shape[0] != 0: if len(k) == 3: conf = k[2] if conf < 0.5: continue cv2.circle(self.im, (int(x_coord), int(y_coord)), radius, color_k, -1, lineType=cv2.LINE_AA) if kpt_line: ndim = kpts.shape[-1] for i, sk in enumerate(self.skeleton): pos1 = (int(kpts[(sk[0] - 1), 0]), int(kpts[(sk[0] - 1), 1])) pos2 = (int(kpts[(sk[1] - 1), 0]), int(kpts[(sk[1] - 1), 1])) if ndim == 3: conf1 = kpts[(sk[0] - 1), 2] conf2 = kpts[(sk[1] - 1), 2] if conf1 < 0.5 or conf2 < 0.5: continue if pos1[0] % shape[1] == 0 or pos1[1] % shape[0] == 0 or pos1[0] < 0 or pos1[1] < 0: continue if pos2[0] % shape[1] == 0 or pos2[1] % shape[0] == 0 or pos2[0] < 0 or pos2[1] < 0: continue cv2.line(self.im, pos1, pos2, [int(x) for x in self.limb_color[i]], thickness=2, lineType=cv2.LINE_AA) if self.pil: # Convert im back to PIL and update draw self.fromarray(self.im) def rectangle(self, xy, fill=None, outline=None, width=1): """Add rectangle to image (PIL-only).""" self.draw.rectangle(xy, fill, outline, width) def text(self, xy, text, txt_color=(255, 255, 255), anchor="top", box_style=False): """Adds text to an image using PIL or cv2.""" if anchor == "bottom": # start y from font bottom w, h = self.font.getsize(text) # text width, height xy[1] += 1 - h if self.pil: if box_style: w, h = self.font.getsize(text) self.draw.rectangle((xy[0], xy[1], xy[0] + w + 1, xy[1] + h + 1), fill=txt_color) # Using `txt_color` for background and draw fg with white color txt_color = (255, 255, 255) if "\n" in text: lines = text.split("\n") _, h = self.font.getsize(text) for line in lines: self.draw.text(xy, line, fill=txt_color, font=self.font) xy[1] += h else: self.draw.text(xy, text, fill=txt_color, font=self.font) else: if box_style: w, h = cv2.getTextSize(text, 0, fontScale=self.sf, thickness=self.tf)[0] # text width, height outside = xy[1] - h >= 3 p2 = xy[0] + w, xy[1] - h - 3 if outside else xy[1] + h + 3 cv2.rectangle(self.im, xy, p2, txt_color, -1, cv2.LINE_AA) # filled # Using `txt_color` for background and draw fg with white color txt_color = (255, 255, 255) cv2.putText(self.im, text, xy, 0, self.sf, txt_color, thickness=self.tf, lineType=cv2.LINE_AA) def fromarray(self, im): """Update self.im from a numpy array.""" self.im = im if isinstance(im, Image.Image) else Image.fromarray(im) self.draw = ImageDraw.Draw(self.im) def result(self): """Return annotated image as array.""" return np.asarray(self.im) def show(self, title=None): """Show the annotated image.""" Image.fromarray(np.asarray(self.im)[..., ::-1]).show(title) def save(self, filename="image.jpg"): """Save the annotated image to 'filename'.""" cv2.imwrite(filename, np.asarray(self.im)) def draw_region(self, reg_pts=None, color=(0, 255, 0), thickness=5): """ Draw region line. Args: reg_pts (list): Region Points (for line 2 points, for region 4 points) color (tuple): Region Color value thickness (int): Region area thickness value """ cv2.polylines(self.im, [np.array(reg_pts, dtype=np.int32)], isClosed=True, color=color, thickness=thickness) def draw_centroid_and_tracks(self, track, color=(255, 0, 255), track_thickness=2): """ Draw centroid point and track trails. Args: track (list): object tracking points for trails display color (tuple): tracks line color track_thickness (int): track line thickness value """ points = np.hstack(track).astype(np.int32).reshape((-1, 1, 2)) cv2.polylines(self.im, [points], isClosed=False, color=color, thickness=track_thickness) cv2.circle(self.im, (int(track[-1][0]), int(track[-1][1])), track_thickness * 2, color, -1) def count_labels(self, counts=0, count_txt_size=2, color=(255, 255, 255), txt_color=(0, 0, 0)): """ Plot counts for object counter. Args: counts (int): objects counts value count_txt_size (int): text size for counts display color (tuple): background color of counts display txt_color (tuple): text color of counts display """ self.tf = count_txt_size tl = self.tf or round(0.002 * (self.im.shape[0] + self.im.shape[1]) / 2) + 1 tf = max(tl - 1, 1) # Get text size for in_count and out_count t_size_in = cv2.getTextSize(str(counts), 0, fontScale=tl / 2, thickness=tf)[0] # Calculate positions for counts label text_width = t_size_in[0] text_x = (self.im.shape[1] - text_width) // 2 # Center x-coordinate text_y = t_size_in[1] # Create a rounded rectangle for in_count cv2.rectangle( self.im, (text_x - 5, text_y - 5), (text_x + text_width + 7, text_y + t_size_in[1] + 7), color, -1 ) cv2.putText( self.im, str(counts), (text_x, text_y + t_size_in[1]), 0, tl / 2, txt_color, self.tf, lineType=cv2.LINE_AA ) @staticmethod def estimate_pose_angle(a, b, c): """ Calculate the pose angle for object. Args: a (float) : The value of pose point a b (float): The value of pose point b c (float): The value o pose point c Returns: angle (degree): Degree value of angle between three points """ a, b, c = np.array(a), np.array(b), np.array(c) radians = np.arctan2(c[1] - b[1], c[0] - b[0]) - np.arctan2(a[1] - b[1], a[0] - b[0]) angle = np.abs(radians * 180.0 / np.pi) if angle > 180.0: angle = 360 - angle return angle def draw_specific_points(self, keypoints, indices=[2, 5, 7], shape=(640, 640), radius=2): """ Draw specific keypoints for gym steps counting. Args: keypoints (list): list of keypoints data to be plotted indices (list): keypoints ids list to be plotted shape (tuple): imgsz for model inference radius (int): Keypoint radius value """ for i, k in enumerate(keypoints): if i in indices: x_coord, y_coord = k[0], k[1] if x_coord % shape[1] != 0 and y_coord % shape[0] != 0: if len(k) == 3: conf = k[2] if conf < 0.5: continue cv2.circle(self.im, (int(x_coord), int(y_coord)), radius, (0, 255, 0), -1, lineType=cv2.LINE_AA) return self.im def plot_angle_and_count_and_stage(self, angle_text, count_text, stage_text, center_kpt, line_thickness=2): """ Plot the pose angle, count value and step stage. Args: angle_text (str): angle value for workout monitoring count_text (str): counts value for workout monitoring stage_text (str): stage decision for workout monitoring center_kpt (int): centroid pose index for workout monitoring line_thickness (int): thickness for text display """ angle_text, count_text, stage_text = (f" {angle_text:.2f}", f"Steps : {count_text}", f" {stage_text}") font_scale = 0.6 + (line_thickness / 10.0) # Draw angle (angle_text_width, angle_text_height), _ = cv2.getTextSize(angle_text, 0, font_scale, line_thickness) angle_text_position = (int(center_kpt[0]), int(center_kpt[1])) angle_background_position = (angle_text_position[0], angle_text_position[1] - angle_text_height - 5) angle_background_size = (angle_text_width + 2 * 5, angle_text_height + 2 * 5 + (line_thickness * 2)) cv2.rectangle( self.im, angle_background_position, ( angle_background_position[0] + angle_background_size[0], angle_background_position[1] + angle_background_size[1], ), (255, 255, 255), -1, ) cv2.putText(self.im, angle_text, angle_text_position, 0, font_scale, (0, 0, 0), line_thickness) # Draw Counts (count_text_width, count_text_height), _ = cv2.getTextSize(count_text, 0, font_scale, line_thickness) count_text_position = (angle_text_position[0], angle_text_position[1] + angle_text_height + 20) count_background_position = ( angle_background_position[0], angle_background_position[1] + angle_background_size[1] + 5, ) count_background_size = (count_text_width + 10, count_text_height + 10 + (line_thickness * 2)) cv2.rectangle( self.im, count_background_position, ( count_background_position[0] + count_background_size[0], count_background_position[1] + count_background_size[1], ), (255, 255, 255), -1, ) cv2.putText(self.im, count_text, count_text_position, 0, font_scale, (0, 0, 0), line_thickness) # Draw Stage (stage_text_width, stage_text_height), _ = cv2.getTextSize(stage_text, 0, font_scale, line_thickness) stage_text_position = (int(center_kpt[0]), int(center_kpt[1]) + angle_text_height + count_text_height + 40) stage_background_position = (stage_text_position[0], stage_text_position[1] - stage_text_height - 5) stage_background_size = (stage_text_width + 10, stage_text_height + 10) cv2.rectangle( self.im, stage_background_position, ( stage_background_position[0] + stage_background_size[0], stage_background_position[1] + stage_background_size[1], ), (255, 255, 255), -1, ) cv2.putText(self.im, stage_text, stage_text_position, 0, font_scale, (0, 0, 0), line_thickness) def seg_bbox(self, mask, mask_color=(255, 0, 255), det_label=None, track_label=None): """ Function for drawing segmented object in bounding box shape. Args: mask (list): masks data list for instance segmentation area plotting mask_color (tuple): mask foreground color det_label (str): Detection label text track_label (str): Tracking label text """ cv2.polylines(self.im, [np.int32([mask])], isClosed=True, color=mask_color, thickness=2) label = f"Track ID: {track_label}" if track_label else det_label text_size, _ = cv2.getTextSize(label, 0, 0.7, 1) cv2.rectangle( self.im, (int(mask[0][0]) - text_size[0] // 2 - 10, int(mask[0][1]) - text_size[1] - 10), (int(mask[0][0]) + text_size[0] // 2 + 5, int(mask[0][1] + 5)), mask_color, -1, ) cv2.putText( self.im, label, (int(mask[0][0]) - text_size[0] // 2, int(mask[0][1]) - 5), 0, 0.7, (255, 255, 255), 2 ) def plot_distance_and_line(self, distance_m, distance_mm, centroids, line_color, centroid_color): """ Plot the distance and line on frame. Args: distance_m (float): Distance between two bbox centroids in meters. distance_mm (float): Distance between two bbox centroids in millimeters. centroids (list): Bounding box centroids data. line_color (RGB): Distance line color. centroid_color (RGB): Bounding box centroid color. """ (text_width_m, text_height_m), _ = cv2.getTextSize( f"Distance M: {distance_m:.2f}m", cv2.FONT_HERSHEY_SIMPLEX, 0.8, 2 ) cv2.rectangle(self.im, (15, 25), (15 + text_width_m + 10, 25 + text_height_m + 20), (255, 255, 255), -1) cv2.putText( self.im, f"Distance M: {distance_m:.2f}m", (20, 50), cv2.FONT_HERSHEY_SIMPLEX, 0.8, (0, 0, 0), 2, cv2.LINE_AA, ) (text_width_mm, text_height_mm), _ = cv2.getTextSize( f"Distance MM: {distance_mm:.2f}mm", cv2.FONT_HERSHEY_SIMPLEX, 0.8, 2 ) cv2.rectangle(self.im, (15, 75), (15 + text_width_mm + 10, 75 + text_height_mm + 20), (255, 255, 255), -1) cv2.putText( self.im, f"Distance MM: {distance_mm:.2f}mm", (20, 100), cv2.FONT_HERSHEY_SIMPLEX, 0.8, (0, 0, 0), 2, cv2.LINE_AA, ) cv2.line(self.im, centroids[0], centroids[1], line_color, 3) cv2.circle(self.im, centroids[0], 6, centroid_color, -1) cv2.circle(self.im, centroids[1], 6, centroid_color, -1) def visioneye(self, box, center_point, color=(235, 219, 11), pin_color=(255, 0, 255), thickness=2, pins_radius=10): """ Function for pinpoint human-vision eye mapping and plotting. Args: box (list): Bounding box coordinates center_point (tuple): center point for vision eye view color (tuple): object centroid and line color value pin_color (tuple): visioneye point color value thickness (int): int value for line thickness pins_radius (int): visioneye point radius value """ center_bbox = int((box[0] + box[2]) / 2), int((box[1] + box[3]) / 2) cv2.circle(self.im, center_point, pins_radius, pin_color, -1) cv2.circle(self.im, center_bbox, pins_radius, color, -1) cv2.line(self.im, center_point, center_bbox, color, thickness) @TryExcept() # known issue https://github.com/ultralytics/yolov5/issues/5395 @plt_settings() def plot_labels(boxes, cls, names=(), save_dir=Path(""), on_plot=None): """Plot training labels including class histograms and box statistics.""" import pandas as pd import seaborn as sn # Filter matplotlib>=3.7.2 warning and Seaborn use_inf and is_categorical FutureWarnings warnings.filterwarnings("ignore", category=UserWarning, message="The figure layout has changed to tight") warnings.filterwarnings("ignore", category=FutureWarning) # Plot dataset labels LOGGER.info(f"Plotting labels to {save_dir / 'labels.jpg'}... ") nc = int(cls.max() + 1) # number of classes boxes = boxes[:1000000] # limit to 1M boxes x = pd.DataFrame(boxes, columns=["x", "y", "width", "height"]) # Seaborn correlogram sn.pairplot(x, corner=True, diag_kind="auto", kind="hist", diag_kws=dict(bins=50), plot_kws=dict(pmax=0.9)) plt.savefig(save_dir / "labels_correlogram.jpg", dpi=200) plt.close() # Matplotlib labels ax = plt.subplots(2, 2, figsize=(8, 8), tight_layout=True)[1].ravel() y = ax[0].hist(cls, bins=np.linspace(0, nc, nc + 1) - 0.5, rwidth=0.8) for i in range(nc): y[2].patches[i].set_color([x / 255 for x in colors(i)]) ax[0].set_ylabel("instances") if 0 < len(names) < 30: ax[0].set_xticks(range(len(names))) ax[0].set_xticklabels(list(names.values()), rotation=90, fontsize=10) else: ax[0].set_xlabel("classes") sn.histplot(x, x="x", y="y", ax=ax[2], bins=50, pmax=0.9) sn.histplot(x, x="width", y="height", ax=ax[3], bins=50, pmax=0.9) # Rectangles boxes[:, 0:2] = 0.5 # center boxes = ops.xywh2xyxy(boxes) * 1000 img = Image.fromarray(np.ones((1000, 1000, 3), dtype=np.uint8) * 255) for cls, box in zip(cls[:500], boxes[:500]): ImageDraw.Draw(img).rectangle(box, width=1, outline=colors(cls)) # plot ax[1].imshow(img) ax[1].axis("off") for a in [0, 1, 2, 3]: for s in ["top", "right", "left", "bottom"]: ax[a].spines[s].set_visible(False) fname = save_dir / "labels.jpg" plt.savefig(fname, dpi=200) plt.close() if on_plot: on_plot(fname) def save_one_box(xyxy, im, file=Path("im.jpg"), gain=1.02, pad=10, square=False, BGR=False, save=True): """ Save image crop as {file} with crop size multiple {gain} and {pad} pixels. Save and/or return crop. This function takes a bounding box and an image, and then saves a cropped portion of the image according to the bounding box. Optionally, the crop can be squared, and the function allows for gain and padding adjustments to the bounding box. Args: xyxy (torch.Tensor or list): A tensor or list representing the bounding box in xyxy format. im (numpy.ndarray): The input image. file (Path, optional): The path where the cropped image will be saved. Defaults to 'im.jpg'. gain (float, optional): A multiplicative factor to increase the size of the bounding box. Defaults to 1.02. pad (int, optional): The number of pixels to add to the width and height of the bounding box. Defaults to 10. square (bool, optional): If True, the bounding box will be transformed into a square. Defaults to False. BGR (bool, optional): If True, the image will be saved in BGR format, otherwise in RGB. Defaults to False. save (bool, optional): If True, the cropped image will be saved to disk. Defaults to True. Returns: (numpy.ndarray): The cropped image. Example: ```python from ultralytics.utils.plotting import save_one_box xyxy = [50, 50, 150, 150] im = cv2.imread('image.jpg') cropped_im = save_one_box(xyxy, im, file='cropped.jpg', square=True) ``` """ if not isinstance(xyxy, torch.Tensor): # may be list xyxy = torch.stack(xyxy) b = ops.xyxy2xywh(xyxy.view(-1, 4)) # boxes if square: b[:, 2:] = b[:, 2:].max(1)[0].unsqueeze(1) # attempt rectangle to square b[:, 2:] = b[:, 2:] * gain + pad # box wh * gain + pad xyxy = ops.xywh2xyxy(b).long() xyxy = ops.clip_boxes(xyxy, im.shape) crop = im[int(xyxy[0, 1]) : int(xyxy[0, 3]), int(xyxy[0, 0]) : int(xyxy[0, 2]), :: (1 if BGR else -1)] if save: file.parent.mkdir(parents=True, exist_ok=True) # make directory f = str(increment_path(file).with_suffix(".jpg")) # cv2.imwrite(f, crop) # save BGR, https://github.com/ultralytics/yolov5/issues/7007 chroma subsampling issue Image.fromarray(crop[..., ::-1]).save(f, quality=95, subsampling=0) # save RGB return crop @threaded def plot_images( images, batch_idx, cls, bboxes=np.zeros(0, dtype=np.float32), confs=None, masks=np.zeros(0, dtype=np.uint8), kpts=np.zeros((0, 51), dtype=np.float32), paths=None, fname="images.jpg", names=None, on_plot=None, max_subplots=16, save=True, conf_thres=0.25, ): """Plot image grid with labels.""" if isinstance(images, torch.Tensor): images = images.cpu().float().numpy() if isinstance(cls, torch.Tensor): cls = cls.cpu().numpy() if isinstance(bboxes, torch.Tensor): bboxes = bboxes.cpu().numpy() if isinstance(masks, torch.Tensor): masks = masks.cpu().numpy().astype(int) if isinstance(kpts, torch.Tensor): kpts = kpts.cpu().numpy() if isinstance(batch_idx, torch.Tensor): batch_idx = batch_idx.cpu().numpy() max_size = 1920 # max image size bs, _, h, w = images.shape # batch size, _, height, width bs = min(bs, max_subplots) # limit plot images ns = np.ceil(bs**0.5) # number of subplots (square) if np.max(images[0]) <= 1: images *= 255 # de-normalise (optional) # Build Image mosaic = np.full((int(ns * h), int(ns * w), 3), 255, dtype=np.uint8) # init for i in range(bs): x, y = int(w * (i // ns)), int(h * (i % ns)) # block origin mosaic[y : y + h, x : x + w, :] = images[i].transpose(1, 2, 0) # Resize (optional) scale = max_size / ns / max(h, w) if scale < 1: h = math.ceil(scale * h) w = math.ceil(scale * w) mosaic = cv2.resize(mosaic, tuple(int(x * ns) for x in (w, h))) # Annotate fs = int((h + w) * ns * 0.01) # font size annotator = Annotator(mosaic, line_width=round(fs / 10), font_size=fs, pil=True, example=names) for i in range(bs): x, y = int(w * (i // ns)), int(h * (i % ns)) # block origin annotator.rectangle([x, y, x + w, y + h], None, (255, 255, 255), width=2) # borders if paths: annotator.text((x + 5, y + 5), text=Path(paths[i]).name[:40], txt_color=(220, 220, 220)) # filenames if len(cls) > 0: idx = batch_idx == i classes = cls[idx].astype("int") labels = confs is None if len(bboxes): boxes = bboxes[idx] conf = confs[idx] if confs is not None else None # check for confidence presence (label vs pred) is_obb = boxes.shape[-1] == 5 # xywhr boxes = ops.xywhr2xyxyxyxy(boxes) if is_obb else ops.xywh2xyxy(boxes) if len(boxes): if boxes[:, :4].max() <= 1.1: # if normalized with tolerance 0.1 boxes[..., 0::2] *= w # scale to pixels boxes[..., 1::2] *= h elif scale < 1: # absolute coords need scale if image scales boxes[..., :4] *= scale boxes[..., 0::2] += x boxes[..., 1::2] += y for j, box in enumerate(boxes.astype(np.int64).tolist()): c = classes[j] color = colors(c) c = names.get(c, c) if names else c if labels or conf[j] > conf_thres: label = f"{c}" if labels else f"{c} {conf[j]:.1f}" annotator.box_label(box, label, color=color, rotated=is_obb) elif len(classes): for c in classes: color = colors(c) c = names.get(c, c) if names else c annotator.text((x, y), f"{c}", txt_color=color, box_style=True) # Plot keypoints if len(kpts): kpts_ = kpts[idx].copy() if len(kpts_): if kpts_[..., 0].max() <= 1.01 or kpts_[..., 1].max() <= 1.01: # if normalized with tolerance .01 kpts_[..., 0] *= w # scale to pixels kpts_[..., 1] *= h elif scale < 1: # absolute coords need scale if image scales kpts_ *= scale kpts_[..., 0] += x kpts_[..., 1] += y for j in range(len(kpts_)): if labels or conf[j] > conf_thres: annotator.kpts(kpts_[j]) # Plot masks if len(masks): if idx.shape[0] == masks.shape[0]: # overlap_masks=False image_masks = masks[idx] else: # overlap_masks=True image_masks = masks[[i]] # (1, 640, 640) nl = idx.sum() index = np.arange(nl).reshape((nl, 1, 1)) + 1 image_masks = np.repeat(image_masks, nl, axis=0) image_masks = np.where(image_masks == index, 1.0, 0.0) im = np.asarray(annotator.im).copy() for j in range(len(image_masks)): if labels or conf[j] > conf_thres: color = colors(classes[j]) mh, mw = image_masks[j].shape if mh != h or mw != w: mask = image_masks[j].astype(np.uint8) mask = cv2.resize(mask, (w, h)) mask = mask.astype(bool) else: mask = image_masks[j].astype(bool) with contextlib.suppress(Exception): im[y : y + h, x : x + w, :][mask] = ( im[y : y + h, x : x + w, :][mask] * 0.4 + np.array(color) * 0.6 ) annotator.fromarray(im) if not save: return np.asarray(annotator.im) annotator.im.save(fname) # save if on_plot: on_plot(fname) @plt_settings() def plot_results(file="path/to/results.csv", dir="", segment=False, pose=False, classify=False, on_plot=None): """ Plot training results from a results CSV file. The function supports various types of data including segmentation, pose estimation, and classification. Plots are saved as 'results.png' in the directory where the CSV is located. Args: file (str, optional): Path to the CSV file containing the training results. Defaults to 'path/to/results.csv'. dir (str, optional): Directory where the CSV file is located if 'file' is not provided. Defaults to ''. segment (bool, optional): Flag to indicate if the data is for segmentation. Defaults to False. pose (bool, optional): Flag to indicate if the data is for pose estimation. Defaults to False. classify (bool, optional): Flag to indicate if the data is for classification. Defaults to False. on_plot (callable, optional): Callback function to be executed after plotting. Takes filename as an argument. Defaults to None. Example: ```python from ultralytics.utils.plotting import plot_results plot_results('path/to/results.csv', segment=True) ``` """ import pandas as pd from scipy.ndimage import gaussian_filter1d save_dir = Path(file).parent if file else Path(dir) if classify: fig, ax = plt.subplots(2, 2, figsize=(6, 6), tight_layout=True) index = [1, 4, 2, 3] elif segment: fig, ax = plt.subplots(2, 8, figsize=(18, 6), tight_layout=True) index = [1, 2, 3, 4, 5, 6, 9, 10, 13, 14, 15, 16, 7, 8, 11, 12] elif pose: fig, ax = plt.subplots(2, 9, figsize=(21, 6), tight_layout=True) index = [1, 2, 3, 4, 5, 6, 7, 10, 11, 14, 15, 16, 17, 18, 8, 9, 12, 13] else: fig, ax = plt.subplots(2, 5, figsize=(12, 6), tight_layout=True) index = [1, 2, 3, 4, 5, 8, 9, 10, 6, 7] ax = ax.ravel() files = list(save_dir.glob("results*.csv")) assert len(files), f"No results.csv files found in {save_dir.resolve()}, nothing to plot." for f in files: try: data = pd.read_csv(f) s = [x.strip() for x in data.columns] x = data.values[:, 0] for i, j in enumerate(index): y = data.values[:, j].astype("float") # y[y == 0] = np.nan # don't show zero values ax[i].plot(x, y, marker=".", label=f.stem, linewidth=2, markersize=8) # actual results ax[i].plot(x, gaussian_filter1d(y, sigma=3), ":", label="smooth", linewidth=2) # smoothing line ax[i].set_title(s[j], fontsize=12) # if j in [8, 9, 10]: # share train and val loss y axes # ax[i].get_shared_y_axes().join(ax[i], ax[i - 5]) except Exception as e: LOGGER.warning(f"WARNING: Plotting error for {f}: {e}") ax[1].legend() fname = save_dir / "results.png" fig.savefig(fname, dpi=200) plt.close() if on_plot: on_plot(fname) def plt_color_scatter(v, f, bins=20, cmap="viridis", alpha=0.8, edgecolors="none"): """ Plots a scatter plot with points colored based on a 2D histogram. Args: v (array-like): Values for the x-axis. f (array-like): Values for the y-axis. bins (int, optional): Number of bins for the histogram. Defaults to 20. cmap (str, optional): Colormap for the scatter plot. Defaults to 'viridis'. alpha (float, optional): Alpha for the scatter plot. Defaults to 0.8. edgecolors (str, optional): Edge colors for the scatter plot. Defaults to 'none'. Examples: >>> v = np.random.rand(100) >>> f = np.random.rand(100) >>> plt_color_scatter(v, f) """ # Calculate 2D histogram and corresponding colors hist, xedges, yedges = np.histogram2d(v, f, bins=bins) colors = [ hist[ min(np.digitize(v[i], xedges, right=True) - 1, hist.shape[0] - 1), min(np.digitize(f[i], yedges, right=True) - 1, hist.shape[1] - 1), ] for i in range(len(v)) ] # Scatter plot plt.scatter(v, f, c=colors, cmap=cmap, alpha=alpha, edgecolors=edgecolors) def plot_tune_results(csv_file="tune_results.csv"): """ Plot the evolution results stored in an 'tune_results.csv' file. The function generates a scatter plot for each key in the CSV, color-coded based on fitness scores. The best-performing configurations are highlighted on the plots. Args: csv_file (str, optional): Path to the CSV file containing the tuning results. Defaults to 'tune_results.csv'. Examples: >>> plot_tune_results('path/to/tune_results.csv') """ import pandas as pd from scipy.ndimage import gaussian_filter1d # Scatter plots for each hyperparameter csv_file = Path(csv_file) data = pd.read_csv(csv_file) num_metrics_columns = 1 keys = [x.strip() for x in data.columns][num_metrics_columns:] x = data.values fitness = x[:, 0] # fitness j = np.argmax(fitness) # max fitness index n = math.ceil(len(keys) ** 0.5) # columns and rows in plot plt.figure(figsize=(10, 10), tight_layout=True) for i, k in enumerate(keys): v = x[:, i + num_metrics_columns] mu = v[j] # best single result plt.subplot(n, n, i + 1) plt_color_scatter(v, fitness, cmap="viridis", alpha=0.8, edgecolors="none") plt.plot(mu, fitness.max(), "k+", markersize=15) plt.title(f"{k} = {mu:.3g}", fontdict={"size": 9}) # limit to 40 characters plt.tick_params(axis="both", labelsize=8) # Set axis label size to 8 if i % n != 0: plt.yticks([]) file = csv_file.with_name("tune_scatter_plots.png") # filename plt.savefig(file, dpi=200) plt.close() LOGGER.info(f"Saved {file}") # Fitness vs iteration x = range(1, len(fitness) + 1) plt.figure(figsize=(10, 6), tight_layout=True) plt.plot(x, fitness, marker="o", linestyle="none", label="fitness") plt.plot(x, gaussian_filter1d(fitness, sigma=3), ":", label="smoothed", linewidth=2) # smoothing line plt.title("Fitness vs Iteration") plt.xlabel("Iteration") plt.ylabel("Fitness") plt.grid(True) plt.legend() file = csv_file.with_name("tune_fitness.png") # filename plt.savefig(file, dpi=200) plt.close() LOGGER.info(f"Saved {file}") def output_to_target(output, max_det=300): """Convert model output to target format [batch_id, class_id, x, y, w, h, conf] for plotting.""" targets = [] for i, o in enumerate(output): box, conf, cls = o[:max_det, :6].cpu().split((4, 1, 1), 1) j = torch.full((conf.shape[0], 1), i) targets.append(torch.cat((j, cls, ops.xyxy2xywh(box), conf), 1)) targets = torch.cat(targets, 0).numpy() return targets[:, 0], targets[:, 1], targets[:, 2:-1], targets[:, -1] def output_to_rotated_target(output, max_det=300): """Convert model output to target format [batch_id, class_id, x, y, w, h, conf] for plotting.""" targets = [] for i, o in enumerate(output): box, conf, cls, angle = o[:max_det].cpu().split((4, 1, 1, 1), 1) j = torch.full((conf.shape[0], 1), i) targets.append(torch.cat((j, cls, box, angle, conf), 1)) targets = torch.cat(targets, 0).numpy() return targets[:, 0], targets[:, 1], targets[:, 2:-1], targets[:, -1] def feature_visualization(x, module_type, stage, n=32, save_dir=Path("runs/detect/exp")): """ Visualize feature maps of a given model module during inference. Args: x (torch.Tensor): Features to be visualized. module_type (str): Module type. stage (int): Module stage within the model. n (int, optional): Maximum number of feature maps to plot. Defaults to 32. save_dir (Path, optional): Directory to save results. Defaults to Path('runs/detect/exp'). """ for m in ["Detect", "Pose", "Segment"]: if m in module_type: return _, channels, height, width = x.shape # batch, channels, height, width if height > 1 and width > 1: f = save_dir / f"stage{stage}_{module_type.split('.')[-1]}_features.png" # filename blocks = torch.chunk(x[0].cpu(), channels, dim=0) # select batch index 0, block by channels n = min(n, channels) # number of plots _, ax = plt.subplots(math.ceil(n / 8), 8, tight_layout=True) # 8 rows x n/8 cols ax = ax.ravel() plt.subplots_adjust(wspace=0.05, hspace=0.05) for i in range(n): ax[i].imshow(blocks[i].squeeze()) # cmap='gray' ax[i].axis("off") LOGGER.info(f"Saving {f}... ({n}/{channels})") plt.savefig(f, dpi=300, bbox_inches="tight") plt.close() np.save(str(f.with_suffix(".npy")), x[0].cpu().numpy()) # npy save