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| import pydiffvg | |
| import torch | |
| import skimage | |
| import numpy as np | |
| # Use GPU if available | |
| pydiffvg.set_use_gpu(torch.cuda.is_available()) | |
| canvas_width, canvas_height = 256, 256 | |
| ellipse = pydiffvg.Ellipse(radius = torch.tensor([60.0, 30.0]), | |
| center = torch.tensor([128.0, 128.0])) | |
| shapes = [ellipse] | |
| ellipse_group = pydiffvg.ShapeGroup(shape_ids = torch.tensor([0]), | |
| fill_color = torch.tensor([0.3, 0.6, 0.3, 1.0])) | |
| shape_groups = [ellipse_group] | |
| scene_args = pydiffvg.RenderFunction.serialize_scene(\ | |
| canvas_width, canvas_height, shapes, shape_groups) | |
| render = pydiffvg.RenderFunction.apply | |
| img = render(256, # width | |
| 256, # height | |
| 2, # num_samples_x | |
| 2, # num_samples_y | |
| 0, # seed | |
| None, # background_image | |
| *scene_args) | |
| # The output image is in linear RGB space. Do Gamma correction before saving the image. | |
| pydiffvg.imwrite(img.cpu(), 'results/single_ellipse/target.png', gamma=2.2) | |
| target = img.clone() | |
| # Move the ellipse to produce initial guess | |
| # normalize radius & center for easier learning rate | |
| radius_n = torch.tensor([20.0 / 256.0, 40.0 / 256.0], requires_grad=True) | |
| center_n = torch.tensor([108.0 / 256.0, 138.0 / 256.0], requires_grad=True) | |
| color = torch.tensor([0.3, 0.2, 0.8, 1.0], requires_grad=True) | |
| ellipse.radius = radius_n * 256 | |
| ellipse.center = center_n * 256 | |
| ellipse_group.fill_color = color | |
| scene_args = pydiffvg.RenderFunction.serialize_scene(\ | |
| canvas_width, canvas_height, shapes, shape_groups) | |
| img = render(256, # width | |
| 256, # height | |
| 2, # num_samples_x | |
| 2, # num_samples_y | |
| 1, # seed | |
| None, # background_image | |
| *scene_args) | |
| pydiffvg.imwrite(img.cpu(), 'results/single_ellipse/init.png', gamma=2.2) | |
| # Optimize for radius & center | |
| optimizer = torch.optim.Adam([radius_n, center_n, color], lr=1e-2) | |
| # Run 50 Adam iterations. | |
| for t in range(50): | |
| print('iteration:', t) | |
| optimizer.zero_grad() | |
| # Forward pass: render the image. | |
| ellipse.radius = radius_n * 256 | |
| ellipse.center = center_n * 256 | |
| ellipse_group.fill_color = color | |
| scene_args = pydiffvg.RenderFunction.serialize_scene(\ | |
| canvas_width, canvas_height, shapes, shape_groups) | |
| img = render(256, # width | |
| 256, # height | |
| 2, # num_samples_x | |
| 2, # num_samples_y | |
| t+1, # seed | |
| None, # background_image | |
| *scene_args) | |
| # Save the intermediate render. | |
| pydiffvg.imwrite(img.cpu(), 'results/single_ellipse/iter_{}.png'.format(t), gamma=2.2) | |
| # Compute the loss function. Here it is L2. | |
| loss = (img - target).pow(2).sum() | |
| print('loss:', loss.item()) | |
| # Backpropagate the gradients. | |
| loss.backward() | |
| # Print the gradients | |
| print('radius.grad:', radius_n.grad) | |
| print('center.grad:', center_n.grad) | |
| print('color.grad:', color.grad) | |
| # Take a gradient descent step. | |
| optimizer.step() | |
| # Print the current params. | |
| print('radius:', ellipse.radius) | |
| print('center:', ellipse.center) | |
| print('color:', ellipse_group.fill_color) | |
| # Render the final result. | |
| ellipse.radius = radius_n * 256 | |
| ellipse.center = center_n * 256 | |
| ellipse_group.fill_color = color | |
| scene_args = pydiffvg.RenderFunction.serialize_scene(\ | |
| canvas_width, canvas_height, shapes, shape_groups) | |
| img = render(256, # width | |
| 256, # height | |
| 2, # num_samples_x | |
| 2, # num_samples_y | |
| 52, # seed | |
| None, # background_image | |
| *scene_args) | |
| # Save the images and differences. | |
| pydiffvg.imwrite(img.cpu(), 'results/single_ellipse/final.png') | |
| # Convert the intermediate renderings to a video. | |
| from subprocess import call | |
| call(["ffmpeg", "-framerate", "24", "-i", | |
| "results/single_ellipse/iter_%d.png", "-vb", "20M", | |
| "results/single_ellipse/out.mp4"]) | |