demo.py

import argparse
import torch
import torch.optim as optim

from painter import *

# settings
parser = argparse.ArgumentParser(description='STYLIZED NEURAL PAINTING')
parser.add_argument('--img_path', type=str, default='./test_images/sunflowers.jpg', metavar='str',
                    help='path to test image (default: ./test_images/sunflowers.jpg)')
parser.add_argument('--renderer', type=str, default='oilpaintbrush', metavar='str',
                    help='renderer: [watercolor, markerpen, oilpaintbrush, rectangle (default oilpaintbrush)')
parser.add_argument('--canvas_color', type=str, default='black', metavar='str',
                    help='canvas_color: [black, white] (default black)')
parser.add_argument('--canvas_size', type=int, default=512, metavar='str',
                    help='size of the canvas for stroke rendering')
parser.add_argument('--keep_aspect_ratio', action='store_true', default=False,
                    help='keep input aspect ratio when saving outputs')
parser.add_argument('--max_m_strokes', type=int, default=500, metavar='str',
                    help='max number of strokes (default 500)')
parser.add_argument('--m_grid', type=int, default=5, metavar='N',
                    help='divide an image to m_grid x m_grid patches (default 5)')
parser.add_argument('--beta_L1', type=float, default=1.0,
                    help='weight for L1 loss (default: 1.0)')
parser.add_argument('--with_ot_loss', action='store_true', default=False,
                    help='imporve the convergence by using optimal transportation loss')
parser.add_argument('--beta_ot', type=float, default=0.1,
                    help='weight for optimal transportation loss (default: 0.1)')
parser.add_argument('--net_G', type=str, default='zou-fusion-net-light', metavar='str',
                    help='net_G: plain-dcgan, plain-unet, huang-net, zou-fusion-net, '
                         'or zou-fusion-net-light (default: zou-fusion-net-light)')
parser.add_argument('--renderer_checkpoint_dir', type=str, default=r'./checkpoints_G_oilpaintbrush_light', metavar='str',
                    help='dir to load neu-renderer (default: ./checkpoints_G_oilpaintbrush_light)')
parser.add_argument('--lr', type=float, default=0.002,
                    help='learning rate for stroke searching (default: 0.005)')
parser.add_argument('--output_dir', type=str, default=r'./output', metavar='str',
                    help='dir to save painting results (default: ./output)')
parser.add_argument('--disable_preview', action='store_true', default=False,
                    help='disable cv2.imshow, for running remotely without x-display')
args = parser.parse_args()


# Decide which device we want to run on
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")


def optimize_x(pt):

    pt._load_checkpoint()
    pt.net_G.eval()

    pt.initialize_params()
    pt.x_ctt.requires_grad = True
    pt.x_color.requires_grad = True
    pt.x_alpha.requires_grad = True
    utils.set_requires_grad(pt.net_G, False)

    pt.optimizer_x = optim.RMSprop([pt.x_ctt, pt.x_color, pt.x_alpha], lr=pt.lr)

    print('begin to draw...')
    pt.step_id = 0
    for pt.anchor_id in range(0, pt.m_strokes_per_block):
        pt.stroke_sampler(pt.anchor_id)
        iters_per_stroke = int(500 / pt.m_strokes_per_block)
        for i in range(iters_per_stroke):

            pt.optimizer_x.zero_grad()

            pt.x_ctt.data = torch.clamp(pt.x_ctt.data, 0.1, 1 - 0.1)
            pt.x_color.data = torch.clamp(pt.x_color.data, 0, 1)
            pt.x_alpha.data = torch.clamp(pt.x_alpha.data, 0, 1)

            if args.canvas_color == 'white':
                pt.G_pred_canvas = torch.ones(
                    [args.m_grid ** 2, 3, pt.net_G.out_size, pt.net_G.out_size]).to(device)
            else:
                pt.G_pred_canvas = torch.zeros(
                    [args.m_grid ** 2, 3, pt.net_G.out_size, pt.net_G.out_size]).to(device)

            pt._forward_pass()
            pt._drawing_step_states()
            pt._backward_x()
            pt.optimizer_x.step()

            pt.x_ctt.data = torch.clamp(pt.x_ctt.data, 0.1, 1 - 0.1)
            pt.x_color.data = torch.clamp(pt.x_color.data, 0, 1)
            pt.x_alpha.data = torch.clamp(pt.x_alpha.data, 0, 1)

            pt.step_id += 1

    v = pt.x.detach().cpu().numpy()
    pt._save_stroke_params(v)
    v_n = pt._normalize_strokes(pt.x)
    v_n = pt._shuffle_strokes_and_reshape(v_n)
    final_rendered_image = pt._render(v_n, save_jpgs=True, save_video=True)



if __name__ == '__main__':

    pt = Painter(args=args)
    optimize_x(pt)