Merge pull request #24 from LielinJiang/first-order

Add first-order-model to applications

applications/first_order_model/configs/vox-256.yaml

+dataset_params:
+  root_dir: data/vox-png
+  frame_shape: [256, 256, 3]
+  id_sampling: True
+  pairs_list: data/vox256.csv
+  augmentation_params:
+    flip_param:
+      horizontal_flip: True
+      time_flip: True
+    jitter_param:
+      brightness: 0.1
+      contrast: 0.1
+      saturation: 0.1
+      hue: 0.1
+
+
+model_params:
+  common_params:
+    num_kp: 10
+    num_channels: 3
+    estimate_jacobian: True
+  kp_detector_params:
+     temperature: 0.1
+     block_expansion: 32
+     max_features: 1024
+     scale_factor: 0.25
+     num_blocks: 5
+  generator_params:
+    block_expansion: 64
+    max_features: 512
+    num_down_blocks: 2
+    num_bottleneck_blocks: 6
+    estimate_occlusion_map: True
+    dense_motion_params:
+      block_expansion: 64
+      max_features: 1024
+      num_blocks: 5
+      scale_factor: 0.25
+  discriminator_params:
+    scales: [1]
+    block_expansion: 32
+    max_features: 512
+    num_blocks: 4
+    sn: True
+
+train_params:
+  num_epochs: 100
+  num_repeats: 75
+  epoch_milestones: [60, 90]
+  lr_generator: 2.0e-4
+  lr_discriminator: 2.0e-4
+  lr_kp_detector: 2.0e-4
+  batch_size: 40
+  scales: [1, 0.5, 0.25, 0.125]
+  checkpoint_freq: 50
+  transform_params:
+    sigma_affine: 0.05
+    sigma_tps: 0.005
+    points_tps: 5
+  loss_weights:
+    generator_gan: 0
+    discriminator_gan: 1
+    feature_matching: [10, 10, 10, 10]
+    perceptual: [10, 10, 10, 10, 10]
+    equivariance_value: 10
+    equivariance_jacobian: 10
+
+reconstruction_params:
+  num_videos: 1000
+  format: '.mp4'
+
+animate_params:
+  num_pairs: 50
+  format: '.mp4'
+  normalization_params:
+    adapt_movement_scale: False
+    use_relative_movement: True
+    use_relative_jacobian: True
+
+visualizer_params:
+  kp_size: 5
+  draw_border: True
+  colormap: 'gist_rainbow'

applications/tools/first-order-demo.py

+import matplotlib
+matplotlib.use('Agg')
+import os
+import sys
+
+import yaml
+import pickle
+from argparse import ArgumentParser
+from tqdm import tqdm
+
+import imageio
+import numpy as np
+from skimage.transform import resize
+from skimage import img_as_ubyte
+import paddle
+
+from ppgan.models.generators.occlusion_aware import OcclusionAwareGenerator
+from ppgan.modules.keypoint_detector import KPDetector
+from ppgan.utils.animate import normalize_kp
+from scipy.spatial import ConvexHull
+
+paddle.disable_static()
+
+if sys.version_info[0] < 3:
+    raise Exception(
+        "You must use Python 3 or higher. Recommended version is Python 3.7")
+
+
+def load_checkpoints(config_path, checkpoint_path, cpu=False):
+
+    with open(config_path) as f:
+        config = yaml.load(f)
+
+    generator = OcclusionAwareGenerator(
+        **config['model_params']['generator_params'],
+        **config['model_params']['common_params'])
+
+    kp_detector = KPDetector(**config['model_params']['kp_detector_params'],
+                             **config['model_params']['common_params'])
+
+    checkpoint = pickle.load(open(checkpoint_path, 'rb'))
+    generator.set_state_dict(checkpoint['generator'])
+
+    kp_detector.set_state_dict(checkpoint['kp_detector'])
+
+    generator.eval()
+    kp_detector.eval()
+
+    return generator, kp_detector
+
+
+def make_animation(source_image,
+                   driving_video,
+                   generator,
+                   kp_detector,
+                   relative=True,
+                   adapt_movement_scale=True,
+                   cpu=False):
+    with paddle.no_grad():
+        predictions = []
+        source = paddle.to_tensor(source_image[np.newaxis].astype(
+            np.float32)).transpose([0, 3, 1, 2])
+        # if not cpu:
+        #     source = source.cuda()
+        driving = paddle.to_tensor(
+            np.array(driving_video)[np.newaxis].astype(np.float32)).transpose(
+                [0, 4, 1, 2, 3])
+        kp_source = kp_detector(source)
+        kp_driving_initial = kp_detector(driving[:, :, 0])
+
+        for frame_idx in tqdm(range(driving.shape[2])):
+            driving_frame = driving[:, :, frame_idx]
+            kp_driving = kp_detector(driving_frame)
+            kp_norm = normalize_kp(kp_source=kp_source,
+                                   kp_driving=kp_driving,
+                                   kp_driving_initial=kp_driving_initial,
+                                   use_relative_movement=relative,
+                                   use_relative_jacobian=relative,
+                                   adapt_movement_scale=adapt_movement_scale)
+            out = generator(source, kp_source=kp_source, kp_driving=kp_norm)
+
+            predictions.append(
+                np.transpose(out['prediction'].numpy(), [0, 2, 3, 1])[0])
+    return predictions
+
+
+def find_best_frame(source, driving, cpu=False):
+    import face_alignment
+
+    def normalize_kp(kp):
+        kp = kp - kp.mean(axis=0, keepdims=True)
+        area = ConvexHull(kp[:, :2]).volume
+        area = np.sqrt(area)
+        kp[:, :2] = kp[:, :2] / area
+        return kp
+
+    fa = face_alignment.FaceAlignment(face_alignment.LandmarksType._2D,
+                                      flip_input=True,
+                                      device='cpu' if cpu else 'cuda')
+    kp_source = fa.get_landmarks(255 * source)[0]
+    kp_source = normalize_kp(kp_source)
+    norm = float('inf')
+    frame_num = 0
+    for i, image in tqdm(enumerate(driving)):
+        kp_driving = fa.get_landmarks(255 * image)[0]
+        kp_driving = normalize_kp(kp_driving)
+        new_norm = (np.abs(kp_source - kp_driving)**2).sum()
+        if new_norm < norm:
+            norm = new_norm
+            frame_num = i
+    return frame_num
+
+
+if __name__ == "__main__":
+    parser = ArgumentParser()
+    parser.add_argument("--config", required=True, help="path to config")
+    parser.add_argument("--checkpoint",
+                        default='vox-cpk.pth.tar',
+                        help="path to checkpoint to restore")
+
+    parser.add_argument("--source_image",
+                        default='sup-mat/source.png',
+                        help="path to source image")
+    parser.add_argument("--driving_video",
+                        default='sup-mat/source.png',
+                        help="path to driving video")
+    parser.add_argument("--result_video",
+                        default='result.mp4',
+                        help="path to output")
+
+    parser.add_argument("--relative",
+                        dest="relative",
+                        action="store_true",
+                        help="use relative or absolute keypoint coordinates")
+    parser.add_argument(
+        "--adapt_scale",
+        dest="adapt_scale",
+        action="store_true",
+        help="adapt movement scale based on convex hull of keypoints")
+
+    parser.add_argument(
+        "--find_best_frame",
+        dest="find_best_frame",
+        action="store_true",
+        help=
+        "Generate from the frame that is the most alligned with source. (Only for faces, requires face_aligment lib)"
+    )
+
+    parser.add_argument("--best_frame",
+                        dest="best_frame",
+                        type=int,
+                        default=None,
+                        help="Set frame to start from.")
+
+    parser.add_argument("--cpu",
+                        dest="cpu",
+                        action="store_true",
+                        help="cpu mode.")
+
+    parser.set_defaults(relative=False)
+    parser.set_defaults(adapt_scale=False)
+
+    opt = parser.parse_args()
+
+    source_image = imageio.imread(opt.source_image)
+    reader = imageio.get_reader(opt.driving_video)
+    fps = reader.get_meta_data()['fps']
+    driving_video = []
+    try:
+        for im in reader:
+            driving_video.append(im)
+    except RuntimeError:
+        pass
+    reader.close()
+
+    source_image = resize(source_image, (256, 256))[..., :3]
+    driving_video = [
+        resize(frame, (256, 256))[..., :3] for frame in driving_video
+    ]
+    generator, kp_detector = load_checkpoints(config_path=opt.config,
+                                              checkpoint_path=opt.checkpoint,
+                                              cpu=opt.cpu)
+
+    if opt.find_best_frame or opt.best_frame is not None:
+        i = opt.best_frame if opt.best_frame is not None else find_best_frame(
+            source_image, driving_video, cpu=opt.cpu)
+        print("Best frame: " + str(i))
+        driving_forward = driving_video[i:]
+        driving_backward = driving_video[:(i + 1)][::-1]
+        predictions_forward = make_animation(
+            source_image,
+            driving_forward,
+            generator,
+            kp_detector,
+            relative=opt.relative,
+            adapt_movement_scale=opt.adapt_scale,
+            cpu=opt.cpu)
+        predictions_backward = make_animation(
+            source_image,
+            driving_backward,
+            generator,
+            kp_detector,
+            relative=opt.relative,
+            adapt_movement_scale=opt.adapt_scale,
+            cpu=opt.cpu)
+        predictions = predictions_backward[::-1] + predictions_forward[1:]
+    else:
+        predictions = make_animation(source_image,
+                                     driving_video,
+                                     generator,
+                                     kp_detector,
+                                     relative=opt.relative,
+                                     adapt_movement_scale=opt.adapt_scale,
+                                     cpu=opt.cpu)
+    imageio.mimsave(opt.result_video,
+                    [img_as_ubyte(frame) for frame in predictions],
+                    fps=fps)

ppgan/models/generators/occlusion_aware.py

+import paddle
+from paddle import nn
+import paddle.nn.functional as F
+from ...modules.first_order import ResBlock2d, SameBlock2d, UpBlock2d, DownBlock2d
+from ...modules.dense_motion import DenseMotionNetwork
+
+
+class OcclusionAwareGenerator(nn.Layer):
+    """
+    Generator that given source image and and keypoints try to transform image according to movement trajectories
+    induced by keypoints. Generator follows Johnson architecture.
+    """
+    def __init__(self,
+                 num_channels,
+                 num_kp,
+                 block_expansion,
+                 max_features,
+                 num_down_blocks,
+                 num_bottleneck_blocks,
+                 estimate_occlusion_map=False,
+                 dense_motion_params=None,
+                 estimate_jacobian=False):
+        super(OcclusionAwareGenerator, self).__init__()
+
+        if dense_motion_params is not None:
+            self.dense_motion_network = DenseMotionNetwork(
+                num_kp=num_kp,
+                num_channels=num_channels,
+                estimate_occlusion_map=estimate_occlusion_map,
+                **dense_motion_params)
+        else:
+            self.dense_motion_network = None
+
+        self.first = SameBlock2d(num_channels,
+                                 block_expansion,
+                                 kernel_size=(7, 7),
+                                 padding=(3, 3))
+
+        down_blocks = []
+        for i in range(num_down_blocks):
+            in_features = min(max_features, block_expansion * (2**i))
+            out_features = min(max_features, block_expansion * (2**(i + 1)))
+            down_blocks.append(
+                DownBlock2d(in_features,
+                            out_features,
+                            kernel_size=(3, 3),
+                            padding=(1, 1)))
+        self.down_blocks = nn.LayerList(down_blocks)
+
+        up_blocks = []
+        for i in range(num_down_blocks):
+            in_features = min(max_features,
+                              block_expansion * (2**(num_down_blocks - i)))
+            out_features = min(max_features,
+                               block_expansion * (2**(num_down_blocks - i - 1)))
+            up_blocks.append(
+                UpBlock2d(in_features,
+                          out_features,
+                          kernel_size=(3, 3),
+                          padding=(1, 1)))
+        self.up_blocks = nn.LayerList(up_blocks)
+
+        self.bottleneck = paddle.nn.Sequential()
+        in_features = min(max_features, block_expansion * (2**num_down_blocks))
+        for i in range(num_bottleneck_blocks):
+            self.bottleneck.add_sublayer(
+                'r' + str(i),
+                ResBlock2d(in_features, kernel_size=(3, 3), padding=(1, 1)))
+
+        self.final = nn.Conv2d(block_expansion,
+                               num_channels,
+                               kernel_size=(7, 7),
+                               padding=(3, 3))
+        self.estimate_occlusion_map = estimate_occlusion_map
+        self.num_channels = num_channels
+
+    def deform_input(self, inp, deformation):
+        _, h_old, w_old, _ = deformation.shape
+        _, _, h, w = inp.shape
+        if h_old != h or w_old != w:
+            deformation = deformation.transpose([0, 3, 1, 2])
+            deformation = F.interpolate(deformation,
+                                        size=(h, w),
+                                        mode='bilinear',
+                                        align_corners=False)
+            deformation = deformation.transpose([0, 2, 3, 1])
+        return F.grid_sample(inp, deformation, align_corners=False)
+
+    def forward(self, source_image, kp_driving, kp_source):
+        # Encoding (downsampling) part
+        out = self.first(source_image)
+        for i in range(len(self.down_blocks)):
+            out = self.down_blocks[i](out)
+
+        # Transforming feature representation according to deformation and occlusion
+        output_dict = {}
+        if self.dense_motion_network is not None:
+            dense_motion = self.dense_motion_network(source_image=source_image,
+                                                     kp_driving=kp_driving,
+                                                     kp_source=kp_source)
+            output_dict['mask'] = dense_motion['mask']
+            output_dict['sparse_deformed'] = dense_motion['sparse_deformed']
+
+            if 'occlusion_map' in dense_motion:
+                occlusion_map = dense_motion['occlusion_map']
+                output_dict['occlusion_map'] = occlusion_map
+            else:
+                occlusion_map = None
+            deformation = dense_motion['deformation']
+            out = self.deform_input(out, deformation)
+
+            if occlusion_map is not None:
+                if out.shape[2] != occlusion_map.shape[2] or out.shape[
+                        3] != occlusion_map.shape[3]:
+                    occlusion_map = F.interpolate(occlusion_map,
+                                                  size=out.shape[2:],
+                                                  mode='bilinear',
+                                                  align_corners=False)
+                out = out * occlusion_map
+
+            output_dict["deformed"] = self.deform_input(source_image,
+                                                        deformation)
+
+        # Decoding part
+        out = self.bottleneck(out)
+        for i in range(len(self.up_blocks)):
+            out = self.up_blocks[i](out)
+        out = self.final(out)
+        out = F.sigmoid(out)
+
+        output_dict["prediction"] = out
+
+        return output_dict

ppgan/modules/dense_motion.py

+import paddle
+import paddle.nn as nn
+import paddle.nn.functional as F
+
+from .first_order import Hourglass, AntiAliasInterpolation2d, make_coordinate_grid, kp2gaussian
+
+
+class DenseMotionNetwork(nn.Layer):
+    """
+    Module that predicting a dense motion from sparse motion representation given by kp_source and kp_driving
+    """
+    def __init__(self,
+                 block_expansion,
+                 num_blocks,
+                 max_features,
+                 num_kp,
+                 num_channels,
+                 estimate_occlusion_map=False,
+                 scale_factor=1,
+                 kp_variance=0.01):
+        super(DenseMotionNetwork, self).__init__()
+        self.hourglass = Hourglass(block_expansion=block_expansion,
+                                   in_features=(num_kp + 1) *
+                                   (num_channels + 1),
+                                   max_features=max_features,
+                                   num_blocks=num_blocks)
+
+        self.mask = nn.Conv2d(self.hourglass.out_filters,
+                              num_kp + 1,
+                              kernel_size=(7, 7),
+                              padding=(3, 3))
+
+        if estimate_occlusion_map:
+            self.occlusion = nn.Conv2d(self.hourglass.out_filters,
+                                       1,
+                                       kernel_size=(7, 7),
+                                       padding=(3, 3))
+        else:
+            self.occlusion = None
+
+        self.num_kp = num_kp
+        self.scale_factor = scale_factor
+        self.kp_variance = kp_variance
+
+        if self.scale_factor != 1:
+            self.down = AntiAliasInterpolation2d(num_channels,
+                                                 self.scale_factor)
+
+    def create_heatmap_representations(self, source_image, kp_driving,
+                                       kp_source):
+        """
+        Eq 6. in the paper H_k(z)
+        """
+        spatial_size = source_image.shape[2:]
+        gaussian_driving = kp2gaussian(kp_driving,
+                                       spatial_size=spatial_size,
+                                       kp_variance=self.kp_variance)
+        gaussian_source = kp2gaussian(kp_source,
+                                      spatial_size=spatial_size,
+                                      kp_variance=self.kp_variance)
+        heatmap = gaussian_driving - gaussian_source
+
+        #adding background feature
+        zeros = paddle.zeros(
+            [heatmap.shape[0], 1, spatial_size[0], spatial_size[1]],
+            heatmap.dtype)  #.type(heatmap.type())
+        heatmap = paddle.concat([zeros, heatmap], axis=1)
+        heatmap = heatmap.unsqueeze(2)
+        return heatmap
+
+    def create_sparse_motions(self, source_image, kp_driving, kp_source):
+        """
+        Eq 4. in the paper T_{s<-d}(z)
+        """
+        bs, _, h, w = source_image.shape
+        identity_grid = make_coordinate_grid((h, w),
+                                             type=kp_source['value'].dtype)
+        identity_grid = identity_grid.reshape([1, 1, h, w, 2])
+        coordinate_grid = identity_grid - kp_driving['value'].reshape(
+            [bs, self.num_kp, 1, 1, 2])
+        if 'jacobian' in kp_driving:
+            jacobian = paddle.matmul(kp_source['jacobian'],
+                                     paddle.inverse(kp_driving['jacobian']))
+            jacobian = jacobian.unsqueeze(-3).unsqueeze(-3)
+            jacobian = paddle.tile(jacobian, [1, 1, h, w, 1, 1])
+            coordinate_grid = paddle.matmul(jacobian,
+                                            coordinate_grid.unsqueeze(-1))
+            coordinate_grid = coordinate_grid.squeeze(-1)
+
+        driving_to_source = coordinate_grid + kp_source['value'].reshape(
+            [bs, self.num_kp, 1, 1, 2])
+
+        #adding background feature
+        identity_grid = paddle.tile(identity_grid, (bs, 1, 1, 1, 1))
+        sparse_motions = paddle.concat([identity_grid, driving_to_source],
+                                       axis=1)
+        return sparse_motions
+
+    def create_deformed_source_image(self, source_image, sparse_motions):
+        """
+        Eq 7. in the paper \hat{T}_{s<-d}(z)
+        """
+        bs, _, h, w = source_image.shape
+        source_repeat = paddle.tile(
+            source_image.unsqueeze(1).unsqueeze(1),
+            [1, self.num_kp + 1, 1, 1, 1, 1
+             ])  #.repeat(1, self.num_kp + 1, 1, 1, 1, 1)
+        source_repeat = source_repeat.reshape(
+            [bs * (self.num_kp + 1), -1, h, w])
+        sparse_motions = sparse_motions.reshape(
+            (bs * (self.num_kp + 1), h, w, -1))
+        sparse_deformed = F.grid_sample(source_repeat,
+                                        sparse_motions,
+                                        align_corners=False)
+        sparse_deformed = sparse_deformed.reshape(
+            (bs, self.num_kp + 1, -1, h, w))
+        return sparse_deformed
+
+    def forward(self, source_image, kp_driving, kp_source):
+        if self.scale_factor != 1:
+            source_image = self.down(source_image)
+
+        bs, _, h, w = source_image.shape
+
+        out_dict = dict()
+        heatmap_representation = self.create_heatmap_representations(
+            source_image, kp_driving, kp_source)
+        sparse_motion = self.create_sparse_motions(source_image, kp_driving,
+                                                   kp_source)
+        deformed_source = self.create_deformed_source_image(
+            source_image, sparse_motion)
+        out_dict['sparse_deformed'] = deformed_source
+
+        input = paddle.concat([heatmap_representation, deformed_source], axis=2)
+        input = input.reshape([bs, -1, h, w])
+
+        prediction = self.hourglass(input)
+
+        mask = self.mask(prediction)
+        mask = F.softmax(mask, axis=1)
+        out_dict['mask'] = mask
+        mask = mask.unsqueeze(2)
+        sparse_motion = sparse_motion.transpose([0, 1, 4, 2, 3])
+        deformation = (sparse_motion * mask).sum(axis=1)
+        deformation = deformation.transpose([0, 2, 3, 1])
+
+        out_dict['deformation'] = deformation
+
+        # Sec. 3.2 in the paper
+        if self.occlusion:
+            occlusion_map = F.sigmoid(self.occlusion(prediction))
+            out_dict['occlusion_map'] = occlusion_map
+
+        return out_dict

ppgan/modules/first_order.py

+import paddle
+import paddle.nn as nn
+import paddle.nn.functional as F
+
+
+def kp2gaussian(kp, spatial_size, kp_variance):
+    """
+    Transform a keypoint into gaussian like representation
+    """
+    mean = kp['value']
+
+    coordinate_grid = make_coordinate_grid(spatial_size, mean.dtype)
+    number_of_leading_dimensions = len(mean.shape) - 1
+    shape = (1, ) * number_of_leading_dimensions + tuple(coordinate_grid.shape)
+    coordinate_grid = coordinate_grid.reshape([*shape])
+    repeats = tuple(mean.shape[:number_of_leading_dimensions]) + (1, 1, 1)
+    coordinate_grid = paddle.tile(coordinate_grid, [*repeats])
+
+    # Preprocess kp shape
+    shape = tuple(mean.shape[:number_of_leading_dimensions]) + (1, 1, 2)
+    mean = mean.reshape(shape)
+
+    mean_sub = (coordinate_grid - mean)
+
+    out = paddle.exp(-0.5 * (mean_sub**2).sum(-1) / kp_variance)
+
+    return out
+
+
+def make_coordinate_grid(spatial_size, type):
+    """
+    Create a meshgrid [-1,1] x [-1,1] of given spatial_size.
+    """
+    h, w = spatial_size
+    x = paddle.arange(w, dtype=type)  #.type(type)
+    y = paddle.arange(h, dtype=type)  #.type(type)
+
+    x = (2 * (x / (w - 1)) - 1)
+    y = (2 * (y / (h - 1)) - 1)
+
+    yy = paddle.tile(y.reshape([-1, 1]), [1, w])
+    xx = paddle.tile(x.reshape([1, -1]), [h, 1])
+
+    meshed = paddle.concat([xx.unsqueeze(2), yy.unsqueeze(2)], 2)
+
+    return meshed
+
+
+class ResBlock2d(nn.Layer):
+    """
+    Res block, preserve spatial resolution.
+    """
+    def __init__(self, in_features, kernel_size, padding):
+        super(ResBlock2d, self).__init__()
+        self.conv1 = nn.Conv2d(in_channels=in_features,
+                               out_channels=in_features,
+                               kernel_size=kernel_size,
+                               padding=padding)
+        self.conv2 = nn.Conv2d(in_channels=in_features,
+                               out_channels=in_features,
+                               kernel_size=kernel_size,
+                               padding=padding)
+        self.norm1 = nn.BatchNorm2d(in_features)
+        self.norm2 = nn.BatchNorm2d(in_features)
+
+    def forward(self, x):
+        out = self.norm1(x)
+        out = F.relu(out)
+        out = self.conv1(out)
+        out = self.norm2(out)
+        out = F.relu(out)
+        out = self.conv2(out)
+        out += x
+        return out
+
+
+class UpBlock2d(nn.Layer):
+    """
+    Upsampling block for use in decoder.
+    """
+    def __init__(self,
+                 in_features,
+                 out_features,
+                 kernel_size=3,
+                 padding=1,
+                 groups=1):
+        super(UpBlock2d, self).__init__()
+
+        self.conv = nn.Conv2d(in_channels=in_features,
+                              out_channels=out_features,
+                              kernel_size=kernel_size,
+                              padding=padding,
+                              groups=groups)
+        self.norm = nn.BatchNorm2d(out_features)
+
+    def forward(self, x):
+        out = F.interpolate(x, scale_factor=2)
+        out = self.conv(out)
+        out = self.norm(out)
+        out = F.relu(out)
+        return out
+
+
+class DownBlock2d(nn.Layer):
+    """
+    Downsampling block for use in encoder.
+    """
+    def __init__(self,
+                 in_features,
+                 out_features,
+                 kernel_size=3,
+                 padding=1,
+                 groups=1):
+        super(DownBlock2d, self).__init__()
+        self.conv = nn.Conv2d(in_channels=in_features,
+                              out_channels=out_features,
+                              kernel_size=kernel_size,
+                              padding=padding,
+                              groups=groups)
+        self.norm = nn.BatchNorm2d(out_features)
+        self.pool = nn.AvgPool2d(kernel_size=(2, 2))
+
+    def forward(self, x):
+        out = self.conv(x)
+        out = self.norm(out)
+        out = F.relu(out)
+        out = self.pool(out)
+        return out
+
+
+class SameBlock2d(nn.Layer):
+    """
+    Simple block, preserve spatial resolution.
+    """
+    def __init__(self,
+                 in_features,
+                 out_features,
+                 groups=1,
+                 kernel_size=3,
+                 padding=1):
+        super(SameBlock2d, self).__init__()
+        self.conv = nn.Conv2d(in_channels=in_features,
+                              out_channels=out_features,
+                              kernel_size=kernel_size,
+                              padding=padding,
+                              groups=groups)
+        self.norm = nn.BatchNorm2d(out_features)
+
+    def forward(self, x):
+        out = self.conv(x)
+        out = self.norm(out)
+        out = F.relu(out)
+        return out
+
+
+class Encoder(nn.Layer):
+    """
+    Hourglass Encoder
+    """
+    def __init__(self,
+                 block_expansion,
+                 in_features,
+                 num_blocks=3,
+                 max_features=256):
+        super(Encoder, self).__init__()
+
+        down_blocks = []
+        for i in range(num_blocks):
+            down_blocks.append(
+                DownBlock2d(in_features if i == 0 else min(
+                    max_features, block_expansion * (2**i)),
+                            min(max_features, block_expansion * (2**(i + 1))),
+                            kernel_size=3,
+                            padding=1))
+        self.down_blocks = nn.LayerList(down_blocks)
+
+    def forward(self, x):
+        outs = [x]
+        for down_block in self.down_blocks:
+            outs.append(down_block(outs[-1]))
+        return outs
+
+
+class Decoder(nn.Layer):
+    """
+    Hourglass Decoder
+    """
+    def __init__(self,
+                 block_expansion,
+                 in_features,
+                 num_blocks=3,
+                 max_features=256):
+        super(Decoder, self).__init__()
+
+        up_blocks = []
+
+        for i in range(num_blocks)[::-1]:
+            in_filters = (1 if i == num_blocks - 1 else 2) * min(
+                max_features, block_expansion * (2**(i + 1)))
+            out_filters = min(max_features, block_expansion * (2**i))
+            up_blocks.append(
+                UpBlock2d(in_filters, out_filters, kernel_size=3, padding=1))
+
+        self.up_blocks = nn.LayerList(up_blocks)
+        self.out_filters = block_expansion + in_features
+
+    def forward(self, x):
+        out = x.pop()
+        for up_block in self.up_blocks:
+            out = up_block(out)
+            skip = x.pop()
+            out = paddle.concat([out, skip], axis=1)
+        return out
+
+
+class Hourglass(nn.Layer):
+    """
+    Hourglass architecture.
+    """
+    def __init__(self,
+                 block_expansion,
+                 in_features,
+                 num_blocks=3,
+                 max_features=256):
+        super(Hourglass, self).__init__()
+        self.encoder = Encoder(block_expansion, in_features, num_blocks,
+                               max_features)
+        self.decoder = Decoder(block_expansion, in_features, num_blocks,
+                               max_features)
+        self.out_filters = self.decoder.out_filters
+
+    def forward(self, x):
+        return self.decoder(self.encoder(x))
+
+
+class AntiAliasInterpolation2d(nn.Layer):
+    """
+    Band-limited downsampling, for better preservation of the input signal.
+    """
+    def __init__(self, channels, scale):
+        super(AntiAliasInterpolation2d, self).__init__()
+        sigma = (1 / scale - 1) / 2
+        kernel_size = 2 * round(sigma * 4) + 1
+        self.ka = kernel_size // 2
+        self.kb = self.ka - 1 if kernel_size % 2 == 0 else self.ka
+
+        kernel_size = [kernel_size, kernel_size]
+        sigma = [sigma, sigma]
+        # The gaussian kernel is the product of the
+        # gaussian function of each dimension.
+        kernel = 1
+        meshgrids = paddle.meshgrid(
+            [paddle.arange(size, dtype='float32') for size in kernel_size])
+        for size, std, mgrid in zip(kernel_size, sigma, meshgrids):
+            mean = (size - 1) / 2
+            kernel *= paddle.exp(-(mgrid - mean)**2 / (2 * std**2))
+
+        # Make sure sum of values in gaussian kernel equals 1.
+        kernel = kernel / paddle.sum(kernel)
+        # Reshape to depthwise convolutional weight
+        kernel = kernel.reshape([1, 1, *kernel.shape])
+        kernel = paddle.tile(kernel, [channels, *[1] * (kernel.dim() - 1)])
+
+        self.register_buffer('weight', kernel)
+        self.groups = channels
+        self.scale = scale
+
+    def forward(self, input):
+        if self.scale == 1.0:
+            return input
+
+        out = F.pad(input, [self.ka, self.kb, self.ka, self.kb])
+        out = F.conv2d(out, weight=self.weight, groups=self.groups)
+        out = F.interpolate(out, scale_factor=[self.scale, self.scale])
+
+        return out

ppgan/modules/keypoint_detector.py

+import paddle
+import paddle.nn as nn
+import paddle.nn.functional as F
+from .first_order import Hourglass, make_coordinate_grid, AntiAliasInterpolation2d
+
+
+class KPDetector(nn.Layer):
+    """
+    Detecting a keypoints. Return keypoint position and jacobian near each keypoint.
+    """
+    def __init__(self,
+                 block_expansion,
+                 num_kp,
+                 num_channels,
+                 max_features,
+                 num_blocks,
+                 temperature,
+                 estimate_jacobian=False,
+                 scale_factor=1,
+                 single_jacobian_map=False,
+                 pad=0):
+        super(KPDetector, self).__init__()
+
+        self.predictor = Hourglass(block_expansion,
+                                   in_features=num_channels,
+                                   max_features=max_features,
+                                   num_blocks=num_blocks)
+
+        self.kp = nn.Conv2d(in_channels=self.predictor.out_filters,
+                            out_channels=num_kp,
+                            kernel_size=(7, 7),
+                            padding=pad)
+
+        if estimate_jacobian:
+            self.num_jacobian_maps = 1 if single_jacobian_map else num_kp
+            self.jacobian = nn.Conv2d(in_channels=self.predictor.out_filters,
+                                      out_channels=4 * self.num_jacobian_maps,
+                                      kernel_size=(7, 7),
+                                      padding=pad)
+            # self.jacobian.weight.data.zero_()
+            # self.jacobian.bias.data.copy_(paddle.tensor([1, 0, 0, 1] * self.num_jacobian_maps, dtype='float32'))
+        else:
+            self.jacobian = None
+
+        self.temperature = temperature
+        self.scale_factor = scale_factor
+        if self.scale_factor != 1:
+            self.down = AntiAliasInterpolation2d(num_channels,
+                                                 self.scale_factor)
+
+    def gaussian2kp(self, heatmap):
+        """
+        Extract the mean and from a heatmap
+        """
+        shape = heatmap.shape
+        heatmap = heatmap.unsqueeze(-1)
+        grid = make_coordinate_grid(shape[2:],
+                                    heatmap.dtype).unsqueeze(0).unsqueeze(0)
+        value = (heatmap * grid).sum(axis=(2, 3))
+
+        kp = {'value': value}
+
+        return kp
+
+    def forward(self, x):
+        if self.scale_factor != 1:
+            x = self.down(x)
+
+        feature_map = self.predictor(x)
+        prediction = self.kp(feature_map)
+
+        final_shape = prediction.shape
+        heatmap = prediction.reshape([final_shape[0], final_shape[1], -1])
+        heatmap = F.softmax(heatmap / self.temperature, axis=2)
+        heatmap = heatmap.reshape([*final_shape])
+
+        out = self.gaussian2kp(heatmap)
+
+        if self.jacobian is not None:
+            jacobian_map = self.jacobian(feature_map)
+            jacobian_map = jacobian_map.reshape([
+                final_shape[0], self.num_jacobian_maps, 4, final_shape[2],
+                final_shape[3]
+            ])
+            heatmap = heatmap.unsqueeze(2)
+
+            jacobian = heatmap * jacobian_map
+            jacobian = jacobian.reshape([final_shape[0], final_shape[1], 4, -1])
+            jacobian = jacobian.sum(axis=-1)
+            jacobian = jacobian.reshape(
+                [jacobian.shape[0], jacobian.shape[1], 2, 2])
+            out['jacobian'] = jacobian
+
+        return out

ppgan/utils/animate.py

+import os
+from tqdm import tqdm
+
+import paddle
+
+import imageio
+from scipy.spatial import ConvexHull
+import numpy as np
+
+
+def normalize_kp(kp_source,
+                 kp_driving,
+                 kp_driving_initial,
+                 adapt_movement_scale=False,
+                 use_relative_movement=False,
+                 use_relative_jacobian=False):
+    if adapt_movement_scale:
+        source_area = ConvexHull(kp_source['value'][0].numpy()).volume
+        driving_area = ConvexHull(kp_driving_initial['value'][0].numpy()).volume
+        adapt_movement_scale = np.sqrt(source_area) / np.sqrt(driving_area)
+    else:
+        adapt_movement_scale = 1
+
+    kp_new = {k: v for k, v in kp_driving.items()}
+
+    if use_relative_movement:
+        kp_value_diff = (kp_driving['value'] - kp_driving_initial['value'])
+        kp_value_diff *= adapt_movement_scale
+        kp_new['value'] = kp_value_diff + kp_source['value']
+
+        if use_relative_jacobian:
+            jacobian_diff = paddle.matmul(
+                kp_driving['jacobian'],
+                paddle.inverse(kp_driving_initial['jacobian']))
+            kp_new['jacobian'] = paddle.matmul(jacobian_diff,
+                                               kp_source['jacobian'])
+
+    return kp_new

requirments.txt

-tqdm
\ No newline at end of file
+tqdm
+PyYAML>=5.1
+scikit-image>=0.14.0
+scipy>=1.1.0