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util_vis.py
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util_vis.py
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import numpy as np
import os,sys,time
import torch
import torch.nn.functional as torch_F
import torchvision
import torchvision.transforms.functional as torchvision_F
import matplotlib.pyplot as plt
from mpl_toolkits.mplot3d.art3d import Poly3DCollection
import PIL
import imageio
from easydict import EasyDict as edict
import camera
@torch.no_grad()
def tb_image(opt,tb,step,group,name,images,num_vis=None,from_range=(0,1),cmap="gray"):
images = preprocess_vis_image(opt,images,from_range=from_range,cmap=cmap)
num_H,num_W = num_vis or opt.tb.num_images
images = images[:num_H*num_W]
image_grid = torchvision.utils.make_grid(images[:,:3],nrow=num_W,pad_value=1.)
if images.shape[1]==4:
mask_grid = torchvision.utils.make_grid(images[:,3:],nrow=num_W,pad_value=1.)[:1]
image_grid = torch.cat([image_grid,mask_grid],dim=0)
tag = "{0}/{1}".format(group,name)
tb.add_image(tag,image_grid,step)
def preprocess_vis_image(opt,images,from_range=(0,1),cmap="gray"):
min,max = from_range
images = (images-min)/(max-min)
images = images.clamp(min=0,max=1).cpu()
if images.shape[1]==1:
images = get_heatmap(opt,images[:,0].cpu(),cmap=cmap)
return images
def dump_images(opt,idx,name,images,masks=None,from_range=(0,1),cmap="gray"):
images = preprocess_vis_image(opt,images,masks=masks,from_range=from_range,cmap=cmap) # [B,3,H,W]
images = images.cpu().permute(0,2,3,1).numpy() # [B,H,W,3]
for i,img in zip(idx,images):
fname = "{}/dump/{}_{}.png".format(opt.output_path,i,name)
img_uint8 = (img*255).astype(np.uint8)
imageio.imsave(fname,img_uint8)
def get_heatmap(opt,gray,cmap): # [N,H,W]
color = plt.get_cmap(cmap)(gray.numpy())
color = torch.from_numpy(color[...,:3]).permute(0,3,1,2).float() # [N,3,H,W]
return color
def color_border(images,colors,width=3):
images_pad = []
for i,image in enumerate(images):
image_pad = torch.ones(3,image.shape[1]+width*2,image.shape[2]+width*2)*(colors[i,:,None,None]/255.0)
image_pad[:,width:-width,width:-width] = image
images_pad.append(image_pad)
images_pad = torch.stack(images_pad,dim=0)
return images_pad
@torch.no_grad()
def vis_cameras(opt,vis,step,poses=[],colors=["blue","magenta"],plot_dist=True):
win_name = "{}/{}".format(opt.group,opt.name)
data = []
# set up plots
centers = []
for pose,color in zip(poses,colors):
pose = pose.detach().cpu()
vertices,faces,wireframe = get_camera_mesh(pose,depth=opt.visdom.cam_depth)
center = vertices[:,-1]
centers.append(center)
# camera centers
data.append(dict(
type="scatter3d",
x=[float(n) for n in center[:,0]],
y=[float(n) for n in center[:,1]],
z=[float(n) for n in center[:,2]],
mode="markers",
marker=dict(color=color,size=3),
))
# colored camera mesh
vertices_merged,faces_merged = merge_meshes(vertices,faces)
data.append(dict(
type="mesh3d",
x=[float(n) for n in vertices_merged[:,0]],
y=[float(n) for n in vertices_merged[:,1]],
z=[float(n) for n in vertices_merged[:,2]],
i=[int(n) for n in faces_merged[:,0]],
j=[int(n) for n in faces_merged[:,1]],
k=[int(n) for n in faces_merged[:,2]],
flatshading=True,
color=color,
opacity=0.05,
))
# camera wireframe
wireframe_merged = merge_wireframes(wireframe)
data.append(dict(
type="scatter3d",
x=wireframe_merged[0],
y=wireframe_merged[1],
z=wireframe_merged[2],
mode="lines",
line=dict(color=color,),
opacity=0.3,
))
if plot_dist:
# distance between two poses (camera centers)
center_merged = merge_centers(centers[:2])
data.append(dict(
type="scatter3d",
x=center_merged[0],
y=center_merged[1],
z=center_merged[2],
mode="lines",
line=dict(color="red",width=4,),
))
if len(centers)==4:
center_merged = merge_centers(centers[2:4])
data.append(dict(
type="scatter3d",
x=center_merged[0],
y=center_merged[1],
z=center_merged[2],
mode="lines",
line=dict(color="red",width=4,),
))
# send data to visdom
vis._send(dict(
data=data,
win="poses",
eid=win_name,
layout=dict(
title="({})".format(step),
autosize=True,
margin=dict(l=30,r=30,b=30,t=30,),
showlegend=False,
yaxis=dict(
scaleanchor="x",
scaleratio=1,
)
),
opts=dict(title="{} poses ({})".format(win_name,step),),
))
def get_camera_mesh(pose,depth=1):
vertices = torch.tensor([[-0.5,-0.5,1],
[0.5,-0.5,1],
[0.5,0.5,1],
[-0.5,0.5,1],
[0,0,0]])*depth
faces = torch.tensor([[0,1,2],
[0,2,3],
[0,1,4],
[1,2,4],
[2,3,4],
[3,0,4]])
vertices = camera.cam2world(vertices[None],pose)
wireframe = vertices[:,[0,1,2,3,0,4,1,2,4,3]]
return vertices,faces,wireframe
def merge_wireframes(wireframe):
wireframe_merged = [[],[],[]]
for w in wireframe:
wireframe_merged[0] += [float(n) for n in w[:,0]]+[None]
wireframe_merged[1] += [float(n) for n in w[:,1]]+[None]
wireframe_merged[2] += [float(n) for n in w[:,2]]+[None]
return wireframe_merged
def merge_meshes(vertices,faces):
mesh_N,vertex_N = vertices.shape[:2]
faces_merged = torch.cat([faces+i*vertex_N for i in range(mesh_N)],dim=0)
vertices_merged = vertices.view(-1,vertices.shape[-1])
return vertices_merged,faces_merged
def merge_centers(centers):
center_merged = [[],[],[]]
for c1,c2 in zip(*centers):
center_merged[0] += [float(c1[0]),float(c2[0]),None]
center_merged[1] += [float(c1[1]),float(c2[1]),None]
center_merged[2] += [float(c1[2]),float(c2[2]),None]
return center_merged
def plot_save_poses(opt,fig,pose,pose_ref=None,path=None,ep=None):
# get the camera meshes
_,_,cam = get_camera_mesh(pose,depth=opt.visdom.cam_depth)
cam = cam.numpy()
if pose_ref is not None:
_,_,cam_ref = get_camera_mesh(pose_ref,depth=opt.visdom.cam_depth)
cam_ref = cam_ref.numpy()
# set up plot window(s)
plt.title("epoch {}".format(ep))
ax1 = fig.add_subplot(121,projection="3d")
ax2 = fig.add_subplot(122,projection="3d")
setup_3D_plot(ax1,elev=-90,azim=-90,lim=edict(x=(-1,1),y=(-1,1),z=(-1,1)))
setup_3D_plot(ax2,elev=0,azim=-90,lim=edict(x=(-1,1),y=(-1,1),z=(-1,1)))
ax1.set_title("forward-facing view",pad=0)
ax2.set_title("top-down view",pad=0)
plt.subplots_adjust(left=0,right=1,bottom=0,top=0.95,wspace=0,hspace=0)
plt.margins(tight=True,x=0,y=0)
# plot the cameras
N = len(cam)
color = plt.get_cmap("gist_rainbow")
for i in range(N):
if pose_ref is not None:
ax1.plot(cam_ref[i,:,0],cam_ref[i,:,1],cam_ref[i,:,2],color=(0.3,0.3,0.3),linewidth=1)
ax2.plot(cam_ref[i,:,0],cam_ref[i,:,1],cam_ref[i,:,2],color=(0.3,0.3,0.3),linewidth=1)
ax1.scatter(cam_ref[i,5,0],cam_ref[i,5,1],cam_ref[i,5,2],color=(0.3,0.3,0.3),s=40)
ax2.scatter(cam_ref[i,5,0],cam_ref[i,5,1],cam_ref[i,5,2],color=(0.3,0.3,0.3),s=40)
c = np.array(color(float(i)/N))*0.8
ax1.plot(cam[i,:,0],cam[i,:,1],cam[i,:,2],color=c)
ax2.plot(cam[i,:,0],cam[i,:,1],cam[i,:,2],color=c)
ax1.scatter(cam[i,5,0],cam[i,5,1],cam[i,5,2],color=c,s=40)
ax2.scatter(cam[i,5,0],cam[i,5,1],cam[i,5,2],color=c,s=40)
png_fname = "{}/{}.png".format(path,ep)
plt.savefig(png_fname,dpi=75)
# clean up
plt.clf()
def plot_save_poses_blender(opt,fig,pose,pose_ref=None,path=None,ep=None):
# get the camera meshes
_,_,cam = get_camera_mesh(pose,depth=opt.visdom.cam_depth)
cam = cam.numpy()
if pose_ref is not None:
_,_,cam_ref = get_camera_mesh(pose_ref,depth=opt.visdom.cam_depth)
cam_ref = cam_ref.numpy()
# set up plot window(s)
ax = fig.add_subplot(111,projection="3d")
ax.set_title("epoch {}".format(ep),pad=0)
setup_3D_plot(ax,elev=45,azim=35,lim=edict(x=(-3,3),y=(-3,3),z=(-3,2.4)))
plt.subplots_adjust(left=0,right=1,bottom=0,top=0.95,wspace=0,hspace=0)
plt.margins(tight=True,x=0,y=0)
# plot the cameras
N = len(cam)
ref_color = (0.7,0.2,0.7)
pred_color = (0,0.6,0.7)
ax.add_collection3d(Poly3DCollection([v[:4] for v in cam_ref],alpha=0.2,facecolor=ref_color))
for i in range(N):
ax.plot(cam_ref[i,:,0],cam_ref[i,:,1],cam_ref[i,:,2],color=ref_color,linewidth=0.5)
ax.scatter(cam_ref[i,5,0],cam_ref[i,5,1],cam_ref[i,5,2],color=ref_color,s=20)
if ep==0:
png_fname = "{}/GT.png".format(path)
plt.savefig(png_fname,dpi=75)
ax.add_collection3d(Poly3DCollection([v[:4] for v in cam],alpha=0.2,facecolor=pred_color))
for i in range(N):
ax.plot(cam[i,:,0],cam[i,:,1],cam[i,:,2],color=pred_color,linewidth=1)
ax.scatter(cam[i,5,0],cam[i,5,1],cam[i,5,2],color=pred_color,s=20)
for i in range(N):
ax.plot([cam[i,5,0],cam_ref[i,5,0]],
[cam[i,5,1],cam_ref[i,5,1]],
[cam[i,5,2],cam_ref[i,5,2]],color=(1,0,0),linewidth=3)
png_fname = "{}/{}.png".format(path,ep)
plt.savefig(png_fname,dpi=75)
# clean up
plt.clf()
def setup_3D_plot(ax,elev,azim,lim=None):
ax.xaxis.set_pane_color((1.0,1.0,1.0,0.0))
ax.yaxis.set_pane_color((1.0,1.0,1.0,0.0))
ax.zaxis.set_pane_color((1.0,1.0,1.0,0.0))
ax.xaxis._axinfo["grid"]["color"] = (0.9,0.9,0.9,1)
ax.yaxis._axinfo["grid"]["color"] = (0.9,0.9,0.9,1)
ax.zaxis._axinfo["grid"]["color"] = (0.9,0.9,0.9,1)
ax.xaxis.set_tick_params(labelsize=8)
ax.yaxis.set_tick_params(labelsize=8)
ax.zaxis.set_tick_params(labelsize=8)
ax.set_xlabel("X",fontsize=16)
ax.set_ylabel("Y",fontsize=16)
ax.set_zlabel("Z",fontsize=16)
ax.set_xlim(lim.x[0],lim.x[1])
ax.set_ylim(lim.y[0],lim.y[1])
ax.set_zlim(lim.z[0],lim.z[1])
ax.view_init(elev=elev,azim=azim)