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evaluate_stereo.py
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evaluate_stereo.py
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import time
import numpy as np
import torch
import torch.nn.functional as F
from torchvision.transforms.functional import hflip
import os
import skimage.io
import cv2
from PIL import Image
from glob import glob
from loss.stereo_metric import d1_metric, thres_metric
from dataloader.stereo.datasets import (FlyingThings3D, KITTI15,
ETH3DStereo, MiddleburyEval3)
from dataloader.stereo import transforms
from utils.utils import InputPadder
from utils.file_io import write_pfm
from utils.visualization import vis_disparity
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
IMAGENET_MEAN = [0.485, 0.456, 0.406]
IMAGENET_STD = [0.229, 0.224, 0.225]
@torch.no_grad()
def create_kitti_submission(model,
output_path='output',
padding_factor=16,
attn_splits_list=False,
corr_radius_list=False,
prop_radius_list=False,
attn_type=None,
num_reg_refine=1,
inference_size=None,
):
""" create submission for the KITTI leaderboard """
model.eval()
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
test_dataset = KITTI15(mode='testing', transform=val_transform)
num_samples = len(test_dataset)
print('Number of test samples: %d' % num_samples)
if not os.path.exists(output_path):
os.makedirs(output_path)
for i, sample in enumerate(test_dataset):
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
left_name = sample['left_name']
if inference_size is None:
padder = InputPadder(left.shape, padding_factor=padding_factor)
left, right = padder.pad(left, right)
else:
ori_size = left.shape[-2:]
left = F.interpolate(left, size=inference_size, mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size, mode='bilinear',
align_corners=True)
pred_disp = model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
# remove padding
if inference_size is None:
pred_disp = padder.unpad(pred_disp)[0] # [H, W]
else:
# resize back
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size, mode='bilinear',
align_corners=True).squeeze(1)[0] # [H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
save_name = os.path.join(output_path, left_name)
skimage.io.imsave(save_name, (pred_disp.cpu().numpy() * 256.).astype(np.uint16))
@torch.no_grad()
def create_eth3d_submission(model,
output_path='output',
padding_factor=16,
attn_type=None,
attn_splits_list=False,
corr_radius_list=False,
prop_radius_list=False,
num_reg_refine=1,
inference_size=None,
submission_mode='train',
save_vis_disp=False,
):
""" create submission for the eth3d stereo leaderboard """
model.eval()
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
test_dataset = ETH3DStereo(mode=submission_mode,
transform=val_transform,
save_filename=True
)
num_samples = len(test_dataset)
print('Number of test samples: %d' % num_samples)
if not os.path.exists(output_path):
os.makedirs(output_path)
fixed_inference_size = inference_size
for i, sample in enumerate(test_dataset):
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
left_name = sample['left_name']
nearest_size = [int(np.ceil(left.size(-2) / padding_factor)) * padding_factor,
int(np.ceil(left.size(-1) / padding_factor)) * padding_factor]
# resize to nearest size or specified size
inference_size = nearest_size if fixed_inference_size is None else fixed_inference_size
assert isinstance(inference_size, list) or isinstance(inference_size, tuple)
ori_size = left.shape[-2:]
if inference_size[0] != ori_size[0] or inference_size[1] != ori_size[1]:
left = F.interpolate(left, size=inference_size, mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size, mode='bilinear',
align_corners=True)
# warpup to measure inference time
if i == 0:
for _ in range(5):
model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)
torch.cuda.synchronize()
time_start = time.perf_counter()
pred_disp = model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
torch.cuda.synchronize()
inference_time = time.perf_counter() - time_start
# resize back
if inference_size[0] != ori_size[0] or inference_size[1] != ori_size[1]:
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size, mode='bilinear',
align_corners=True).squeeze(1)[0] # [H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
filename = os.path.basename(os.path.dirname(left_name))
if save_vis_disp:
save_name = os.path.join(output_path, filename + '.png')
disp = vis_disparity(pred_disp.cpu().numpy())
cv2.imwrite(save_name, disp)
else:
save_disp_name = os.path.join(output_path, filename + '.pfm')
# save disp
write_pfm(save_disp_name, pred_disp.cpu().numpy())
# save runtime
save_runtime_name = os.path.join(output_path, filename + '.txt')
with open(save_runtime_name, 'w') as f:
f.write('runtime ' + str(inference_time))
@torch.no_grad()
def create_middlebury_submission(model,
output_path='output',
padding_factor=16,
attn_type=None,
attn_splits_list=False,
corr_radius_list=False,
prop_radius_list=False,
num_reg_refine=1,
inference_size=None,
submission_mode='train',
save_vis_disp=False,
):
""" create submission for the Middlebury leaderboard """
model.eval()
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
test_dataset = MiddleburyEval3(mode=submission_mode,
resolution='F',
transform=val_transform,
save_filename=True,
)
num_samples = len(test_dataset)
print('Number of test samples: %d' % num_samples)
if not os.path.exists(output_path):
os.makedirs(output_path)
for i, sample in enumerate(test_dataset):
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
left_name = sample['left_name']
if inference_size is None:
padder = InputPadder(left.shape, padding_factor=padding_factor)
left, right = padder.pad(left, right)
else:
ori_size = left.shape[-2:]
left = F.interpolate(left, size=inference_size, mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size, mode='bilinear',
align_corners=True)
# warpup to measure inference time
if i == 0:
for _ in range(5):
model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)
torch.cuda.synchronize()
time_start = time.perf_counter()
pred_disp = model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
torch.cuda.synchronize()
inference_time = time.perf_counter() - time_start
# remove padding
if inference_size is None:
pred_disp = padder.unpad(pred_disp)[0] # [H, W]
else:
# resize back
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size, mode='bilinear',
align_corners=True).squeeze(1)[0] # [H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
filename = os.path.basename(os.path.dirname(left_name)) # works for both windows and linux
if save_vis_disp:
save_name = os.path.join(output_path, filename + '.png')
disp = vis_disparity(pred_disp.cpu().numpy())
cv2.imwrite(save_name, disp)
else:
save_disp_dir = os.path.join(output_path, filename)
os.makedirs(save_disp_dir, exist_ok=True)
save_disp_name = os.path.join(save_disp_dir, 'disp0GMStereo.pfm')
# save disp
write_pfm(save_disp_name, pred_disp.cpu().numpy())
# save runtime
save_runtime_name = os.path.join(save_disp_dir, 'timeGMStereo.txt')
with open(save_runtime_name, 'w') as f:
f.write(str(inference_time))
@torch.no_grad()
def validate_things(model,
max_disp=400,
padding_factor=16,
inference_size=None,
attn_type=None,
num_iters_per_scale=None,
attn_splits_list=None,
corr_radius_list=None,
prop_radius_list=None,
num_reg_refine=1,
):
model.eval()
results = {}
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
val_dataset = FlyingThings3D(mode='TEST', transform=val_transform)
num_samples = len(val_dataset)
print('=> %d samples found in the validation set' % num_samples)
val_epe = 0
val_d1 = 0
valid_samples = 0
for i, sample in enumerate(val_dataset):
if i % 1000 == 0:
print('=> Validating %d/%d' % (i, num_samples))
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
gt_disp = sample['disp'].to(device) # [H, W]
if inference_size is None:
padder = InputPadder(left.shape, padding_factor=padding_factor)
left, right = padder.pad(left, right)
else:
ori_size = left.shape[-2:]
left = F.interpolate(left, size=inference_size, mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size, mode='bilinear',
align_corners=True)
mask = (gt_disp > 0) & (gt_disp < max_disp)
if not mask.any():
continue
valid_samples += 1
with torch.no_grad():
pred_disp = model(left, right,
attn_type=attn_type,
num_iters_per_scale=num_iters_per_scale,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
# remove padding
if inference_size is None:
pred_disp = padder.unpad(pred_disp)[0] # [H, W]
else:
# resize back
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size, mode='bilinear',
align_corners=True).squeeze(1)[0] # [H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
epe = F.l1_loss(gt_disp[mask], pred_disp[mask], reduction='mean')
d1 = d1_metric(pred_disp, gt_disp, mask)
val_epe += epe.item()
val_d1 += d1.item()
mean_epe = val_epe / valid_samples
mean_d1 = val_d1 / valid_samples
print('Validation things EPE: %.3f, D1: %.4f' % (
mean_epe, mean_d1))
results['things_epe'] = mean_epe
results['things_d1'] = mean_d1
return results
@torch.no_grad()
def validate_kitti15(model,
padding_factor=16,
inference_size=None,
attn_type=None,
attn_splits_list=None,
corr_radius_list=None,
prop_radius_list=None,
num_reg_refine=1,
count_time=False,
debug=False,
):
model.eval()
results = {}
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
val_dataset = KITTI15(transform=val_transform,
)
num_samples = len(val_dataset)
print('=> %d samples found in the validation set' % num_samples)
val_epe = 0
val_d1 = 0
val_thres3 = 0
if count_time:
total_time = 0
num_runs = 100
valid_samples = 0
for i, sample in enumerate(val_dataset):
if debug and i > 10:
break
if i % 100 == 0:
print('=> Validating %d/%d' % (i, num_samples))
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
gt_disp = sample['disp'].to(device) # [H, W]
if inference_size is None:
padder = InputPadder(left.shape, padding_factor=padding_factor)
left, right = padder.pad(left, right)
else:
ori_size = left.shape[-2:]
left = F.interpolate(left, size=inference_size, mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size, mode='bilinear',
align_corners=True)
mask = gt_disp > 0
if not mask.any():
continue
valid_samples += 1
if count_time and i >= 5:
torch.cuda.synchronize()
time_start = time.perf_counter()
with torch.no_grad():
pred_disp = model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
if count_time and i >= 5:
torch.cuda.synchronize()
total_time += time.perf_counter() - time_start
if i >= num_runs + 4:
break
# remove padding
if inference_size is None:
pred_disp = padder.unpad(pred_disp)[0] # [H, W]
else:
# resize back
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size, mode='bilinear',
align_corners=True).squeeze(1)[0] # [H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
epe = F.l1_loss(gt_disp[mask], pred_disp[mask], reduction='mean')
d1 = d1_metric(pred_disp, gt_disp, mask)
thres3 = thres_metric(pred_disp, gt_disp, mask, 3.0)
val_epe += epe.item()
val_d1 += d1.item()
val_thres3 += thres3.item()
mean_epe = val_epe / valid_samples
mean_d1 = val_d1 / valid_samples
mean_thres3 = val_thres3 / valid_samples
print('Validation KITTI15 EPE: %.3f, D1: %.4f, 3px: %.4f' % (
mean_epe, mean_d1, mean_thres3))
results['kitti15_epe'] = mean_epe
results['kitti15_d1'] = mean_d1
results['kitti15_3px'] = mean_thres3
if count_time:
print('Time: %.6fs' % (total_time / num_runs))
return results
@torch.no_grad()
def validate_eth3d(model,
padding_factor=16,
inference_size=None,
attn_type=None,
attn_splits_list=None,
corr_radius_list=None,
prop_radius_list=None,
num_reg_refine=1,
):
model.eval()
results = {}
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
val_dataset = ETH3DStereo(transform=val_transform,
)
num_samples = len(val_dataset)
print('=> %d samples found in the validation set' % num_samples)
val_epe = 0
val_d1 = 0
val_thres1 = 0
valid_samples = 0
for i, sample in enumerate(val_dataset):
if i % 100 == 0:
print('=> Validating %d/%d' % (i, num_samples))
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
gt_disp = sample['disp'].to(device) # [H, W]
if inference_size is None:
padder = InputPadder(left.shape, padding_factor=padding_factor)
left, right = padder.pad(left, right)
else:
ori_size = left.shape[-2:]
left = F.interpolate(left, size=inference_size, mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size, mode='bilinear',
align_corners=True)
mask = gt_disp > 0
if not mask.any():
continue
valid_samples += 1
with torch.no_grad():
pred_disp = model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
# remove padding
if inference_size is None:
pred_disp = padder.unpad(pred_disp)[0] # [H, W]
else:
# resize back
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size, mode='bilinear',
align_corners=True).squeeze(1)[0] # [H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
epe = F.l1_loss(gt_disp[mask], pred_disp[mask], reduction='mean')
d1 = d1_metric(pred_disp, gt_disp, mask)
thres1 = thres_metric(pred_disp, gt_disp, mask, 1.0)
val_epe += epe.item()
val_d1 += d1.item()
val_thres1 += thres1.item()
mean_epe = val_epe / valid_samples
mean_thres1 = val_thres1 / valid_samples
print('Validation ETH3D EPE: %.3f, 1px: %.4f' % (
mean_epe, mean_thres1))
results['eth3d_epe'] = mean_epe
results['eth3d_1px'] = mean_thres1
return results
@torch.no_grad()
def validate_middlebury(model,
padding_factor=16,
inference_size=None,
attn_type=None,
attn_splits_list=None,
corr_radius_list=None,
prop_radius_list=None,
num_reg_refine=1,
resolution='H',
):
model.eval()
results = {}
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
val_dataset = MiddleburyEval3(transform=val_transform,
resolution=resolution,
)
num_samples = len(val_dataset)
print('=> %d samples found in the validation set' % num_samples)
val_epe = 0
val_d1 = 0
val_thres2 = 0
valid_samples = 0
for i, sample in enumerate(val_dataset):
if i % 100 == 0:
print('=> Validating %d/%d' % (i, num_samples))
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
gt_disp = sample['disp'].to(device) # [H, W]
if inference_size is None:
padder = InputPadder(left.shape, padding_factor=padding_factor)
left, right = padder.pad(left, right)
else:
ori_size = left.shape[-2:]
left = F.interpolate(left, size=inference_size,
mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size,
mode='bilinear',
align_corners=True)
mask = gt_disp > 0
if not mask.any():
continue
valid_samples += 1
with torch.no_grad():
pred_disp = model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
# remove padding
if inference_size is None:
pred_disp = padder.unpad(pred_disp)[0] # [H, W]
else:
# resize back
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size,
mode='bilinear',
align_corners=True).squeeze(1)[0] # [H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
epe = F.l1_loss(gt_disp[mask], pred_disp[mask], reduction='mean')
d1 = d1_metric(pred_disp, gt_disp, mask)
thres2 = thres_metric(pred_disp, gt_disp, mask, 2.0)
val_epe += epe.item()
val_d1 += d1.item()
val_thres2 += thres2.item()
mean_epe = val_epe / valid_samples
mean_thres2 = val_thres2 / valid_samples
print('Validation Middlebury EPE: %.3f, 2px: %.4f' % (
mean_epe, mean_thres2))
results['middlebury_epe'] = mean_epe
results['middlebury_2px'] = mean_thres2
return results
@torch.no_grad()
def inference_stereo(model,
inference_dir=None,
inference_dir_left=None,
inference_dir_right=None,
output_path='output',
padding_factor=16,
inference_size=None,
attn_type=None,
attn_splits_list=None,
corr_radius_list=None,
prop_radius_list=None,
num_reg_refine=1,
pred_bidir_disp=False,
pred_right_disp=False,
save_pfm_disp=False,
):
model.eval()
val_transform_list = [transforms.ToTensor(),
transforms.Normalize(mean=IMAGENET_MEAN, std=IMAGENET_STD)
]
val_transform = transforms.Compose(val_transform_list)
if not os.path.exists(output_path):
os.makedirs(output_path)
assert inference_dir or (inference_dir_left and inference_dir_right)
if inference_dir is not None:
filenames = sorted(glob(inference_dir + '/*.png') + glob(inference_dir + '/*.jpg'))
left_filenames = filenames[::2]
right_filenames = filenames[1::2]
else:
left_filenames = sorted(glob(inference_dir_left + '/*.png') + glob(inference_dir_left + '/*.jpg'))
right_filenames = sorted(glob(inference_dir_right + '/*.png') + glob(inference_dir_right + '/*.jpg'))
assert len(left_filenames) == len(right_filenames)
num_samples = len(left_filenames)
print('%d test samples found' % num_samples)
fixed_inference_size = inference_size
for i in range(num_samples):
if (i + 1) % 50 == 0:
print('predicting %d/%d' % (i + 1, num_samples))
left_name = left_filenames[i]
right_name = right_filenames[i]
left = np.array(Image.open(left_name).convert('RGB')).astype(np.float32)
right = np.array(Image.open(right_name).convert('RGB')).astype(np.float32)
sample = {'left': left, 'right': right}
sample = val_transform(sample)
left = sample['left'].to(device).unsqueeze(0) # [1, 3, H, W]
right = sample['right'].to(device).unsqueeze(0) # [1, 3, H, W]
nearest_size = [int(np.ceil(left.size(-2) / padding_factor)) * padding_factor,
int(np.ceil(left.size(-1) / padding_factor)) * padding_factor]
# resize to nearest size or specified size
inference_size = nearest_size if fixed_inference_size is None else fixed_inference_size
ori_size = left.shape[-2:]
if inference_size[0] != ori_size[0] or inference_size[1] != ori_size[1]:
left = F.interpolate(left, size=inference_size,
mode='bilinear',
align_corners=True)
right = F.interpolate(right, size=inference_size,
mode='bilinear',
align_corners=True)
with torch.no_grad():
if pred_bidir_disp:
new_left, new_right = hflip(right), hflip(left)
left = torch.cat((left, new_left), dim=0)
right = torch.cat((right, new_right), dim=0)
if pred_right_disp:
left, right = hflip(right), hflip(left)
pred_disp = model(left, right,
attn_type=attn_type,
attn_splits_list=attn_splits_list,
corr_radius_list=corr_radius_list,
prop_radius_list=prop_radius_list,
num_reg_refine=num_reg_refine,
task='stereo',
)['flow_preds'][-1] # [1, H, W]
if inference_size[0] != ori_size[0] or inference_size[1] != ori_size[1]:
# resize back
pred_disp = F.interpolate(pred_disp.unsqueeze(1), size=ori_size,
mode='bilinear',
align_corners=True).squeeze(1) # [1, H, W]
pred_disp = pred_disp * ori_size[-1] / float(inference_size[-1])
save_name = os.path.join(output_path, os.path.basename(left_name)[:-4] + '_disp.png')
if pred_right_disp:
pred_disp = hflip(pred_disp)
disp = pred_disp[0].cpu().numpy()
if save_pfm_disp:
save_name_pfm = save_name[:-4] + '.pfm'
write_pfm(save_name_pfm, disp)
disp = vis_disparity(disp)
cv2.imwrite(save_name, disp)
if pred_bidir_disp:
assert pred_disp.size(0) == 2 # [2, H, W]
save_name = os.path.join(output_path, os.path.basename(left_name)[:-4] + '_disp_right.png')
# flip back
disp = hflip(pred_disp[1]).cpu().numpy()
if save_pfm_disp:
save_name_pfm = save_name[:-4] + '.pfm'
write_pfm(save_name_pfm, disp)
disp = vis_disparity(disp)
cv2.imwrite(save_name, disp)
print('Done!')