| import os |
| import cv2 |
| import numpy as np |
| from mpl_toolkits.mplot3d import Axes3D |
| import matplotlib.pyplot as plt |
| import matplotlib as mpl |
| import os |
| import sys |
| os.environ["PYOPENGL_PLATFORM"] = "egl" |
| from pytorch3d.structures import Meshes, Pointclouds |
| from pytorch3d.renderer import ( |
| PointLights, |
| DirectionalLights, |
| PerspectiveCameras, |
| Materials, |
| SoftPhongShader, |
| RasterizationSettings, |
| MeshRenderer, |
| MeshRendererWithFragments, |
| MeshRasterizer, |
| TexturesVertex, |
| PointsRasterizationSettings, |
| PointsRenderer, |
| PointsRasterizer, |
| AlphaCompositor |
| ) |
| import torch |
| import torch.nn as nn |
|
|
| def vis_keypoints_with_skeleton(img, kps, kps_lines, kp_thresh=0.4, alpha=1): |
| |
| cmap = plt.get_cmap('rainbow') |
| colors = [cmap(i) for i in np.linspace(0, 1, len(kps_lines) + 2)] |
| colors = [(c[2] * 255, c[1] * 255, c[0] * 255) for c in colors] |
|
|
| |
| kp_mask = np.copy(img) |
|
|
| |
| for l in range(len(kps_lines)): |
| i1 = kps_lines[l][0] |
| i2 = kps_lines[l][1] |
| p1 = kps[0, i1].astype(np.int32), kps[1, i1].astype(np.int32) |
| p2 = kps[0, i2].astype(np.int32), kps[1, i2].astype(np.int32) |
| if kps[2, i1] > kp_thresh and kps[2, i2] > kp_thresh: |
| cv2.line( |
| kp_mask, p1, p2, |
| color=colors[l], thickness=2, lineType=cv2.LINE_AA) |
| if kps[2, i1] > kp_thresh: |
| cv2.circle( |
| kp_mask, p1, |
| radius=3, color=colors[l], thickness=-1, lineType=cv2.LINE_AA) |
| if kps[2, i2] > kp_thresh: |
| cv2.circle( |
| kp_mask, p2, |
| radius=3, color=colors[l], thickness=-1, lineType=cv2.LINE_AA) |
|
|
| |
| return cv2.addWeighted(img, 1.0 - alpha, kp_mask, alpha, 0) |
|
|
| def vis_keypoints(img, kps, alpha=1): |
| |
| cmap = plt.get_cmap('rainbow') |
| colors = [cmap(i) for i in np.linspace(0, 1, len(kps) + 2)] |
| colors = [(c[2] * 255, c[1] * 255, c[0] * 255) for c in colors] |
|
|
| |
| kp_mask = np.copy(img) |
|
|
| |
| for i in range(len(kps)): |
| p = kps[i][0].astype(np.int32), kps[i][1].astype(np.int32) |
| cv2.circle(kp_mask, p, radius=3, color=colors[i], thickness=-1, lineType=cv2.LINE_AA) |
|
|
| |
| return cv2.addWeighted(img, 1.0 - alpha, kp_mask, alpha, 0) |
|
|
|
|
| def render_mesh(mesh, face, cam_param, bkg, blend_ratio=1.0, return_bg_mask=False, R=None, T=None, return_fragments=False): |
| mesh = mesh.cuda()[None,:,:] |
| face = torch.LongTensor(face.astype(np.int64)).cuda()[None,:,:] |
| cam_param = {k: v.cuda()[None,:] for k,v in cam_param.items()} |
| render_shape = (bkg.shape[0], bkg.shape[1]) |
|
|
| batch_size, vertex_num = mesh.shape[:2] |
| textures = TexturesVertex(verts_features=torch.ones((batch_size,vertex_num,3)).float().cuda()) |
| mesh = torch.stack((-mesh[:,:,0], -mesh[:,:,1], mesh[:,:,2]),2) |
| mesh = Meshes(mesh, face, textures) |
|
|
| if R is None: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device='cuda', |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).cuda().view(1,2)) |
| else: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device='cuda', |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).cuda().view(1,2), |
| R=R, |
| T=T) |
| |
| raster_settings = RasterizationSettings(image_size=render_shape, blur_radius=0.0, faces_per_pixel=1, bin_size=0) |
| rasterizer = MeshRasterizer(cameras=cameras, raster_settings=raster_settings).cuda() |
| lights = PointLights(device='cuda') |
| shader = SoftPhongShader(device='cuda', cameras=cameras, lights=lights) |
| materials = Materials( |
| device='cuda', |
| specular_color=[[0.0, 0.0, 0.0]], |
| shininess=0.0 |
| ) |
|
|
| |
| with torch.no_grad(): |
| renderer = MeshRendererWithFragments(rasterizer=rasterizer, shader=shader) |
| images, fragments = renderer(mesh, materials=materials) |
| |
| |
| is_bkg = (fragments.zbuf <= 0).float().cpu().numpy()[0] |
| render = images[0,:,:,:3].cpu().numpy() |
| fg = render * blend_ratio + bkg/255 * (1 - blend_ratio) |
| render = fg * (1 - is_bkg) * 255 + bkg * is_bkg |
| ret = [render] |
| if return_bg_mask: |
| ret.append(is_bkg) |
| if return_fragments: |
| ret.append(fragments) |
| return tuple(ret) |
|
|
|
|
| def rasterize_mesh(mesh, face, cam_param, height, width, return_bg_mask=False, R=None, T=None): |
| mesh = mesh.cuda()[None,:,:] |
| face = face.long().cuda()[None,:,:] |
| cam_param = {k: v.cuda()[None,:] for k,v in cam_param.items()} |
| render_shape = (height, width) |
|
|
| batch_size, vertex_num = mesh.shape[:2] |
| textures = TexturesVertex(verts_features=torch.ones((batch_size,vertex_num,3)).float().cuda()) |
| mesh = torch.stack((-mesh[:,:,0], -mesh[:,:,1], mesh[:,:,2]),2) |
| mesh = Meshes(mesh, face, textures) |
|
|
| if R is None: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device='cuda', |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).cuda().view(1,2)) |
| else: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device='cuda', |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).cuda().view(1,2), |
| R=R, |
| T=T) |
| |
| raster_settings = RasterizationSettings(image_size=render_shape, blur_radius=0.0, faces_per_pixel=1, bin_size=0) |
| rasterizer = MeshRasterizer(cameras=cameras, raster_settings=raster_settings).cuda() |
|
|
| |
| fragments = rasterizer(mesh) |
|
|
| ret = [fragments] |
|
|
| if return_bg_mask: |
| |
| is_bkg = (fragments.zbuf <= 0).float().cpu().numpy()[0] |
| ret.append(is_bkg) |
|
|
| return tuple(ret) |
|
|
|
|
| def rasterize_points(points, cam_param, height, width, return_bg_mask=False, R=None, T=None, to_cpu=False, points_per_pixel=5, radius=0.01): |
| points = torch.stack((-points[:, 0], -points[:, 1], points[:, 2]), 1) |
| device = points.device |
| if len(points.shape) == 2: |
| points = [points] |
| pointclouds = Pointclouds(points=points) |
| cam_param = {k: v.to(device)[None,:] for k,v in cam_param.items()} |
| render_shape = (height, width) |
|
|
| if R is None: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device=device, |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).to(device).view(1,2)) |
| else: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device=device, |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).to(device).view(1,2), |
| R=R, |
| T=T) |
| |
| raster_settings = PointsRasterizationSettings(image_size=render_shape, radius=radius, points_per_pixel=points_per_pixel, max_points_per_bin=82000) |
| rasterizer = PointsRasterizer(cameras=cameras, raster_settings=raster_settings).to(device) |
|
|
| |
| fragments = rasterizer(pointclouds) |
|
|
| |
| ret = [fragments] |
| if return_bg_mask: |
| if to_cpu: |
| is_bkg = (fragments.zbuf <= 0).all(dim=-1, keepdim=True).float().cpu().numpy()[0] |
| else: |
| is_bkg = (fragments.zbuf <= 0).all(dim=-1, keepdim=True).float()[0] |
| ret.append(is_bkg) |
| |
| return tuple(ret) |
|
|
|
|
| def render_points(points, cam_param, bkg, blend_ratio=1.0, return_bg_mask=False, R=None, T=None, return_fragments=False, rgbs=None): |
| points = torch.stack((-points[:, 0], -points[:, 1], points[:, 2]), 1) |
| if rgbs is None: |
| rgbs = torch.ones_like(points) |
| if len(points.shape) == 2: |
| points = [points] |
| rgbs = [rgbs] |
| pointclouds = Pointclouds(points=points, features=rgbs).cuda() |
| cam_param = {k: v.cuda()[None,:] for k,v in cam_param.items()} |
| render_shape = (bkg.shape[0], bkg.shape[1]) |
|
|
| if R is None: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device='cuda', |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).cuda().view(1,2)) |
| else: |
| cameras = PerspectiveCameras(focal_length=cam_param['focal'], |
| principal_point=cam_param['princpt'], |
| device='cuda', |
| in_ndc=False, |
| image_size=torch.LongTensor(render_shape).cuda().view(1,2), |
| R=R, |
| T=T) |
| |
| raster_settings = PointsRasterizationSettings(image_size=render_shape, radius=0.01, points_per_pixel=5) |
| rasterizer = PointsRasterizer(cameras=cameras, raster_settings=raster_settings).cuda() |
|
|
| |
| with torch.no_grad(): |
| fragments = rasterizer(pointclouds) |
| renderer = PointsRenderer(rasterizer=rasterizer, compositor=AlphaCompositor(background_color=(0, 0, 0))) |
| images = renderer(pointclouds) |
| |
| |
| is_bkg = (fragments.zbuf <= 0).all(dim=-1, keepdim=True).float().cpu().numpy()[0] |
| render = images[0,:,:,:3].cpu().numpy() |
| fg = render * blend_ratio + bkg/255 * (1 - blend_ratio) |
| render = fg * (1 - is_bkg) * 255 + bkg * is_bkg |
|
|
| ret = [render] |
| if return_bg_mask: |
| ret.append(is_bkg) |
| if return_fragments: |
| ret.append(fragments) |
| return tuple(ret) |
|
|
|
|
| class RenderMesh(nn.Module): |
| def __init__(self, image_size, obj_filename=None, faces=None, device='cpu'): |
| super(RenderMesh, self).__init__() |
| self.device = device |
| self.image_size = image_size |
| if obj_filename is not None: |
| verts, faces, aux = load_obj(obj_filename, load_textures=False) |
| self.faces = faces.verts_idx |
| elif faces is not None: |
| import numpy as np |
| self.faces = torch.tensor(faces.astype(np.int32)) |
| else: |
| raise NotImplementedError('Must have faces.') |
| self.raster_settings = RasterizationSettings(image_size=image_size, blur_radius=0.0, faces_per_pixel=1) |
| self.lights = PointLights(device=device, location=[[0.0, 0.0, 3.0]]) |
|
|
| def _build_cameras(self, transform_matrix, focal_length, principal_point=None, intr=None): |
| batch_size = transform_matrix.shape[0] |
| screen_size = torch.tensor( |
| [self.image_size, self.image_size], device=self.device |
| ).float()[None].repeat(batch_size, 1) |
| if principal_point is None: |
| principal_point = torch.zeros(batch_size, 2, device=self.device).float() |
| |
| |
| if intr is None: |
| cameras_kwargs = { |
| 'principal_point': principal_point, 'focal_length': focal_length, |
| 'image_size': screen_size, 'device': self.device, |
| } |
| else: |
| cameras_kwargs = { |
| 'principal_point': principal_point, 'focal_length': torch.tensor([intr[0, 0], intr[1, 1]]).unsqueeze(0), |
| 'image_size': screen_size, 'device': self.device, |
| } |
| cameras = PerspectiveCameras(**cameras_kwargs, R=transform_matrix[:, :3, :3], T=transform_matrix[:, :3, 3]) |
| return cameras |
|
|
| def forward( |
| self, vertices, cameras=None, transform_matrix=None, focal_length=None, principal_point=None, only_rasterize=False, intr=None, |
| ): |
| if cameras is None: |
| cameras = self._build_cameras(transform_matrix, focal_length, principal_point=principal_point, intr=intr) |
| faces = self.faces[None].repeat(vertices.shape[0], 1, 1) |
| |
| verts_rgb = torch.ones_like(vertices) |
| textures = TexturesVertex(verts_features=verts_rgb.to(self.device)) |
| mesh = Meshes( |
| verts=vertices.to(self.device), |
| faces=faces.to(self.device), |
| textures=textures |
| ) |
| renderer = MeshRendererWithFragments( |
| rasterizer=MeshRasterizer(cameras=cameras, raster_settings=self.raster_settings), |
| shader=SoftPhongShader(cameras=cameras, lights=self.lights, device=self.device) |
| ) |
| render_results, fragments = renderer(mesh) |
| render_results = render_results.permute(0, 3, 1, 2) |
| if only_rasterize: |
| return fragments |
| images = render_results[:, :3] |
| alpha_images = render_results[:, 3:] |
| images[alpha_images.expand(-1, 3, -1, -1)<0.5] = 0.0 |
| return images*255, alpha_images |
|
|
|
|
| class RenderPoints(nn.Module): |
| def __init__(self, image_size, obj_filename=None, device='cpu'): |
| super(RenderPoints, self).__init__() |
| self.device = device |
| self.image_size = image_size |
| if obj_filename is not None: |
| verts = load_obj(obj_filename, load_textures=False) |
| self.raster_settings = PointsRasterizationSettings(image_size=image_size, radius=0.01, points_per_pixel=1) |
| self.lights = PointLights(device=device, location=[[0.0, 0.0, 3.0]]) |
|
|
| def _build_cameras(self, transform_matrix, focal_length, principal_point=None): |
| batch_size = transform_matrix.shape[0] |
| screen_size = torch.tensor( |
| [self.image_size, self.image_size], device=self.device |
| ).float()[None].repeat(batch_size, 1) |
| if principal_point is None: |
| principal_point = torch.zeros(batch_size, 2, device=self.device).float() |
| |
| |
| cameras_kwargs = { |
| 'principal_point': principal_point, 'focal_length': focal_length, |
| 'image_size': screen_size, 'device': self.device, |
| } |
| cameras = PerspectiveCameras(**cameras_kwargs, R=transform_matrix[:, :3, :3], T=transform_matrix[:, :3, 3]) |
| return cameras |
|
|
| def forward( |
| self, vertices, cameras=None, transform_matrix=None, focal_length=None, principal_point=None, only_rasterize=False |
| ): |
| if cameras is None: |
| cameras = self._build_cameras(transform_matrix, focal_length, principal_point=principal_point) |
| |
| verts_rgb = torch.ones_like(vertices) |
| pointclouds = Pointclouds(points=vertices, features=verts_rgb).cuda() |
|
|
| |
| rasterizer = PointsRasterizer(cameras=cameras, raster_settings=self.raster_settings).cuda() |
| if only_rasterize: |
| fragments = rasterizer(pointclouds) |
| return fragments |
| renderer = PointsRenderer(rasterizer=rasterizer, compositor=AlphaCompositor(background_color=(0, 0, 0))) |
| render_results = renderer(pointclouds).permute(0, 3, 1, 2) |
| images = render_results[:, :3] |
| alpha_images = render_results[:, 3:] |
|
|
| return images*255, alpha_images |