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shapenet_model_evaluation.py
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shapenet_model_evaluation.py
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from dataset.ShapeNetDataset import *
from torch.utils.data import DataLoader
import argparse
import torch
import torch.nn as nn
import torch.optim as optim
from torch.autograd import Variable
from losses.emd import emd_module as emd
from losses.chamfer import champfer_loss as chamfer
from models.hole_residual import MSNmodel, NormalModel
from utils.utils import weights_init, visdom_show_pc, save_paths, save_model, vis_curve
from utils.metrics import AverageValueMeter
from utils.pcutils import mean_min_square_distance, save_point_cloud
from losses.MDS import MDS_module
import sys
from extensions.chamfer_dist import ChamferDistance
class DevNull:
def write(self, msg):
pass
#Only for testing
parser = argparse.ArgumentParser()
parser.add_argument('--batchSize', type=int, default=1, help='input batch size')
parser.add_argument('--model', type=str, default = 'model', help='optional reload model path')
parser.add_argument('--workers', type=int, help='number of data loading workers', default=1)
parser.add_argument('--nepoch', type=int, default=100, help='number of epochs to train for')
parser.add_argument('--num_points', type=int, default = 2048, help='number of points')
parser.add_argument('--loss', type=str, default = "emd", help='loss distance')
parser.add_argument('--visualize', type=bool, default = True, help='bool visualize')
parser.add_argument('--vis_step', type=int, default = 30, help='visualize step')
parser.add_argument('--vis_step_test', type=int, default = 20, help='visualize test step')
parser.add_argument('--net_alfa', type=float, default = 2000, help='net loss weight')
parser.add_argument('--vis_port', type=int, default = 8997, help='visdom_port')
parser.add_argument('--vis_port_test', type=int, default = 8998, help='visdom_port')
parser.add_argument('--vis_env', type=str, default = "ENV", help='visdom environment')
parser.add_argument('--gpu_n', type=int, default = 0, help='cuda gpu device number')
parser.add_argument('--lrate', type=float, default = 0.001, help='learning rate')
parser.add_argument('--n_primitives', type=int, default = 16, help='number of primitives')
parser.add_argument('--holeSize', type=int, default=35, help='hole size')
parser.add_argument('--outputFolder', type=str, default='', help='Folder output')
opt = parser.parse_args()
# -------------------------------- Load network----------------------------------------
device = torch.device("cuda:" + str(opt.gpu_n) if torch.cuda.is_available() else "cpu")
if torch.cuda.is_available():
print("Using cuda device")
torch.cuda.set_device(device)
network = MSNmodel(opt.num_points, device).to(device)
network.apply(weights_init)
network.cuda()
#load model
print(opt.model, os.path.isfile(opt.model + "/model.pth"))
if opt.model != '' and os.path.isfile(opt.model + "/model.pth"):
model_checkpoint = torch.load(opt.model + "/model.pth",map_location='cuda:0')
residual_checkpoint = torch.load(opt.model + "/residual.pth",map_location='cuda:0')
print("Model network weights loaded ")
network.model.load_state_dict(model_checkpoint['state_dict'])
network.residual.load_state_dict(residual_checkpoint['state_dict'])
print(f'************************** Our - {opt.holeSize/100} ***********************************')
# Shapenet
n_models = 13
class_choice = {'Airplane': 0, 'Bag': 1, 'Cap': 2, 'Car': 3, 'Chair': 4, 'Guitar': 6, 'Lamp': 8, 'Laptop': 9, 'Motorbike': 10, 'Mug': 11, 'Pistol': 12, 'Skateboard': 14, 'Table': 15}
categories = class_choice.keys()
R = []
chamfer_dist = ChamferDistance()
#Reproducibility
torch.backends.cudnn.deterministic = True
torch.backends.cudnn.benchmark = False
torch.manual_seed(1)
torch.cuda.manual_seed_all(1)
np.random.seed(1)
random.seed(1)
for categorie in categories:
pred_error = AverageValueMeter()
gt_error = AverageValueMeter()
chamfer_error = AverageValueMeter()
dataset_dir = './data/shapenet_part'
dataset_test = ShapeNetDataset(root_dir=dataset_dir, class_choice={categorie}, npoints=2048, split='test', hole_size=opt.holeSize/100)
dataloader_test = DataLoader(dataset_test, batch_size=opt.batchSize, shuffle=True, num_workers=0)
network.model.eval()
network.residual.eval()
L = []
with torch.no_grad():
for i, data in enumerate(dataloader_test, 0):
name, in_partial, in_hole, in_complete = data
in_partial = in_partial.contiguous().float().to(device)
in_hole = in_hole.contiguous().float().to(device)
in_complete = in_complete.contiguous().float().to(device)
output, output2, rec_loss1, rec_loss2, exp_loss,_,_ = network(in_partial, in_hole, in_complete, 0.005, 50)
dist = chamfer_dist(output2, in_complete)
chamfer_error.update(dist.item()*10000)
pred = output2.cpu().numpy()[0]
gt = in_complete.cpu().numpy()[0]
partial = in_partial.cpu().numpy()[0]
hole = in_hole.cpu().numpy()[0]
pred_error.update(mean_min_square_distance(pred, gt)*10000)
gt_error.update(mean_min_square_distance(gt, pred)*10000)
#Save models and metric
log_table = {"name":name, "chamfer": dist.item()*10000}
L.append(log_table)
#print(name)
save_point_cloud(os.path.join(opt.outputFolder, categorie, name[0]+'_gt.xyz'), gt)
save_point_cloud(os.path.join(opt.outputFolder, categorie, name[0]+'_partial.xyz'), partial)
save_point_cloud(os.path.join(opt.outputFolder, categorie, name[0]+'_pred.xyz'), pred)
save_point_cloud(os.path.join(opt.outputFolder, categorie, name[0]+'_hole.xyz'), hole)
gt_error.end_epoch()
pred_error.end_epoch()
chamfer_error.end_epoch()
with open(os.path.join(opt.outputFolder, categorie+".txt"), 'w') as fi:
fi.write(json.dumps(L))
R.append({'cat': categorie, 'chamfer': chamfer_error.avg, 'pred': pred_error.avg, 'gt':gt_error.avg})
print('Categorie:', end='\t')
print('Chamfer:', end='\t')
print('Pred->GT:', end='\t')
print('GT->Pred:', end='\t')
print()
for dc in R:
print(dc['cat'], end='\t')
print(dc['chamfer'], end='\t')
print(dc['pred'], end='\t')
print(dc['gt'], end='\t')
print()