| import base64 |
| import math |
| import re |
| from io import BytesIO |
|
|
| import matplotlib.cm |
| import numpy as np |
| import torch |
| import torch.nn |
| from PIL import Image |
|
|
|
|
| class RunningAverage: |
| def __init__(self): |
| self.avg = 0 |
| self.count = 0 |
|
|
| def append(self, value): |
| self.avg = (value + self.count * self.avg) / (self.count + 1) |
| self.count += 1 |
|
|
| def get_value(self): |
| return self.avg |
|
|
|
|
| def denormalize(x, device='cpu'): |
| mean = torch.Tensor([0.485, 0.456, 0.406]).view(1, 3, 1, 1).to(device) |
| std = torch.Tensor([0.229, 0.224, 0.225]).view(1, 3, 1, 1).to(device) |
| return x * std + mean |
|
|
|
|
| class RunningAverageDict: |
| def __init__(self): |
| self._dict = None |
|
|
| def update(self, new_dict): |
| if self._dict is None: |
| self._dict = dict() |
| for key, value in new_dict.items(): |
| self._dict[key] = RunningAverage() |
|
|
| for key, value in new_dict.items(): |
| self._dict[key].append(value) |
|
|
| def get_value(self): |
| return {key: value.get_value() for key, value in self._dict.items()} |
|
|
|
|
| def colorize(value, vmin=10, vmax=1000, cmap='magma_r'): |
| value = value.cpu().numpy()[0, :, :] |
| invalid_mask = value == -1 |
|
|
| |
| vmin = value.min() if vmin is None else vmin |
| vmax = value.max() if vmax is None else vmax |
| if vmin != vmax: |
| value = (value - vmin) / (vmax - vmin) |
| else: |
| |
| value = value * 0. |
| |
| |
| cmapper = matplotlib.cm.get_cmap(cmap) |
| value = cmapper(value, bytes=True) |
| value[invalid_mask] = 255 |
| img = value[:, :, :3] |
|
|
| |
| return img |
|
|
|
|
| def count_parameters(model): |
| return sum(p.numel() for p in model.parameters() if p.requires_grad) |
|
|
|
|
| def compute_errors(gt, pred): |
| thresh = np.maximum((gt / pred), (pred / gt)) |
| a1 = (thresh < 1.25).mean() |
| a2 = (thresh < 1.25 ** 2).mean() |
| a3 = (thresh < 1.25 ** 3).mean() |
|
|
| abs_rel = np.mean(np.abs(gt - pred) / gt) |
| sq_rel = np.mean(((gt - pred) ** 2) / gt) |
|
|
| rmse = (gt - pred) ** 2 |
| rmse = np.sqrt(rmse.mean()) |
|
|
| rmse_log = (np.log(gt) - np.log(pred)) ** 2 |
| rmse_log = np.sqrt(rmse_log.mean()) |
|
|
| err = np.log(pred) - np.log(gt) |
| silog = np.sqrt(np.mean(err ** 2) - np.mean(err) ** 2) * 100 |
|
|
| log_10 = (np.abs(np.log10(gt) - np.log10(pred))).mean() |
| return dict(a1=a1, a2=a2, a3=a3, abs_rel=abs_rel, rmse=rmse, log_10=log_10, rmse_log=rmse_log, |
| silog=silog, sq_rel=sq_rel) |
|
|
|
|
| |
| def b64_to_pil(b64string): |
| image_data = re.sub('^data:image/.+;base64,', '', b64string) |
| |
| return Image.open(BytesIO(base64.b64decode(image_data))) |
|
|
|
|
| |
| from scipy import ndimage |
|
|
|
|
| def edges(d): |
| dx = ndimage.sobel(d, 0) |
| dy = ndimage.sobel(d, 1) |
| return np.abs(dx) + np.abs(dy) |
|
|
|
|
| class PointCloudHelper(): |
| def __init__(self, width=640, height=480): |
| self.xx, self.yy = self.worldCoords(width, height) |
|
|
| def worldCoords(self, width=640, height=480): |
| hfov_degrees, vfov_degrees = 57, 43 |
| hFov = math.radians(hfov_degrees) |
| vFov = math.radians(vfov_degrees) |
| cx, cy = width / 2, height / 2 |
| fx = width / (2 * math.tan(hFov / 2)) |
| fy = height / (2 * math.tan(vFov / 2)) |
| xx, yy = np.tile(range(width), height), np.repeat(range(height), width) |
| xx = (xx - cx) / fx |
| yy = (yy - cy) / fy |
| return xx, yy |
|
|
| def depth_to_points(self, depth): |
| depth[edges(depth) > 0.3] = np.nan |
| length = depth.shape[0] * depth.shape[1] |
| |
| z = depth.reshape(length) |
|
|
| return np.dstack((self.xx * z, self.yy * z, z)).reshape((length, 3)) |
|
|
| |
|
|
