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""" |
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2D visualization primitives based on Matplotlib. |
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1) Plot images with `plot_images`. |
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2) Call `plot_keypoints` or `plot_matches` any number of times. |
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3) Optionally: save a .png or .pdf plot (nice in papers!) with `save_plot`. |
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""" |
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import matplotlib |
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import matplotlib.pyplot as plt |
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import matplotlib.patheffects as path_effects |
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import numpy as np |
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import torch |
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def cm_RdGn(x): |
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"""Custom colormap: red (0) -> yellow (0.5) -> green (1).""" |
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x = np.clip(x, 0, 1)[..., None]*2 |
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c = x*np.array([[0, 1., 0]]) + (2-x)*np.array([[1., 0, 0]]) |
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return np.clip(c, 0, 1) |
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def cm_BlRdGn(x_): |
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"""Custom colormap: blue (-1) -> red (0.0) -> green (1).""" |
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x = np.clip(x_, 0, 1)[..., None]*2 |
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c = x*np.array([[0, 1., 0, 1.]]) + (2-x)*np.array([[1., 0, 0, 1.]]) |
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xn = -np.clip(x_, -1, 0)[..., None]*2 |
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cn = xn*np.array([[0, 0.1, 1, 1.]]) + (2-xn)*np.array([[1., 0, 0, 1.]]) |
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out = np.clip(np.where(x_[..., None] < 0, cn, c), 0, 1) |
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return out |
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def cm_prune(x_): |
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""" Custom colormap to visualize pruning """ |
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if isinstance(x_, torch.Tensor): |
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x_ = x_.cpu().numpy() |
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max_i = max(x_) |
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norm_x = np.where(x_ == max_i, -1, (x_-1) / 9) |
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return cm_BlRdGn(norm_x) |
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def plot_images(imgs, titles=None, cmaps='gray', dpi=100, pad=.5, |
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adaptive=True): |
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"""Plot a set of images horizontally. |
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Args: |
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imgs: list of NumPy RGB (H, W, 3) or PyTorch RGB (3, H, W) or mono (H, W). |
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titles: a list of strings, as titles for each image. |
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cmaps: colormaps for monochrome images. |
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adaptive: whether the figure size should fit the image aspect ratios. |
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""" |
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imgs = [img.permute(1, 2, 0).cpu().numpy() |
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if (isinstance(img, torch.Tensor) and img.dim() == 3) else img |
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for img in imgs] |
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n = len(imgs) |
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if not isinstance(cmaps, (list, tuple)): |
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cmaps = [cmaps] * n |
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if adaptive: |
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ratios = [i.shape[1] / i.shape[0] for i in imgs] |
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else: |
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ratios = [4/3] * n |
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figsize = [sum(ratios)*4.5, 4.5] |
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fig, ax = plt.subplots( |
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1, n, figsize=figsize, dpi=dpi, gridspec_kw={'width_ratios': ratios}) |
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if n == 1: |
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ax = [ax] |
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for i in range(n): |
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ax[i].imshow(imgs[i], cmap=plt.get_cmap(cmaps[i])) |
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ax[i].get_yaxis().set_ticks([]) |
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ax[i].get_xaxis().set_ticks([]) |
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ax[i].set_axis_off() |
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for spine in ax[i].spines.values(): |
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spine.set_visible(False) |
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if titles: |
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ax[i].set_title(titles[i]) |
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fig.tight_layout(pad=pad) |
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def plot_keypoints(kpts, colors='lime', ps=4, axes=None, a=1.0): |
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"""Plot keypoints for existing images. |
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Args: |
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kpts: list of ndarrays of size (N, 2). |
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colors: string, or list of list of tuples (one for each keypoints). |
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ps: size of the keypoints as float. |
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""" |
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if not isinstance(colors, list): |
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colors = [colors] * len(kpts) |
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if not isinstance(a, list): |
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a = [a] * len(kpts) |
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if axes is None: |
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axes = plt.gcf().axes |
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for ax, k, c, alpha in zip(axes, kpts, colors, a): |
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if isinstance(k, torch.Tensor): |
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k = k.cpu().numpy() |
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ax.scatter(k[:, 0], k[:, 1], c=c, s=ps, linewidths=0, alpha=alpha) |
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def plot_matches(kpts0, kpts1, color=None, lw=1.5, ps=4, a=1., labels=None, |
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axes=None): |
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"""Plot matches for a pair of existing images. |
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Args: |
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kpts0, kpts1: corresponding keypoints of size (N, 2). |
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color: color of each match, string or RGB tuple. Random if not given. |
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lw: width of the lines. |
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ps: size of the end points (no endpoint if ps=0) |
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indices: indices of the images to draw the matches on. |
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a: alpha opacity of the match lines. |
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""" |
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fig = plt.gcf() |
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if axes is None: |
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ax = fig.axes |
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ax0, ax1 = ax[0], ax[1] |
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else: |
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ax0, ax1 = axes |
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if isinstance(kpts0, torch.Tensor): |
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kpts0 = kpts0.cpu().numpy() |
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if isinstance(kpts1, torch.Tensor): |
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kpts1 = kpts1.cpu().numpy() |
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assert len(kpts0) == len(kpts1) |
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if color is None: |
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color = matplotlib.cm.hsv(np.random.rand(len(kpts0))).tolist() |
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elif len(color) > 0 and not isinstance(color[0], (tuple, list)): |
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color = [color] * len(kpts0) |
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if lw > 0: |
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for i in range(len(kpts0)): |
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line = matplotlib.patches.ConnectionPatch( |
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xyA=(kpts0[i, 0], kpts0[i, 1]), xyB=(kpts1[i, 0], kpts1[i, 1]), |
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coordsA=ax0.transData, coordsB=ax1.transData, |
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axesA=ax0, axesB=ax1, |
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zorder=1, color=color[i], linewidth=lw, clip_on=True, |
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alpha=a, label=None if labels is None else labels[i], |
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picker=5.0) |
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line.set_annotation_clip(True) |
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fig.add_artist(line) |
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ax0.autoscale(enable=False) |
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ax1.autoscale(enable=False) |
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if ps > 0: |
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ax0.scatter(kpts0[:, 0], kpts0[:, 1], c=color, s=ps) |
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ax1.scatter(kpts1[:, 0], kpts1[:, 1], c=color, s=ps) |
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def add_text(idx, text, pos=(0.01, 0.99), fs=15, color='w', |
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lcolor='k', lwidth=2, ha='left', va='top'): |
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ax = plt.gcf().axes[idx] |
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t = ax.text(*pos, text, fontsize=fs, ha=ha, va=va, |
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color=color, transform=ax.transAxes) |
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if lcolor is not None: |
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t.set_path_effects([ |
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path_effects.Stroke(linewidth=lwidth, foreground=lcolor), |
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path_effects.Normal()]) |
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def save_plot(path, **kw): |
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"""Save the current figure without any white margin.""" |
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plt.savefig(path, bbox_inches='tight', pad_inches=0, **kw) |
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