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colab_interpolate.py
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colab_interpolate.py
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import time
import os
from torch.autograd import Variable
import torch
import numpy as np
import numpy
import networks
from my_args import args
from imageio import imread, imsave
from AverageMeter import *
import shutil
import datetime
torch.backends.cudnn.benchmark = True
model = networks.__dict__[args.netName](
channel = args.channels,
filter_size = args.filter_size,
timestep = args.time_step,
training = False)
if args.use_cuda:
model = model.cuda()
model_path = './model_weights/best.pth'
if not os.path.exists(model_path):
print("*****************************************************************")
print("**** We couldn't load any trained weights ***********************")
print("*****************************************************************")
exit(1)
if args.use_cuda:
pretrained_dict = torch.load(model_path)
else:
pretrained_dict = torch.load(model_path, map_location=lambda storage, loc: storage)
model_dict = model.state_dict()
# 1. filter out unnecessary keys
pretrained_dict = {k: v for k, v in pretrained_dict.items() if k in model_dict}
# 2. overwrite entries in the existing state dict
model_dict.update(pretrained_dict)
# 3. load the new state dict
model.load_state_dict(model_dict)
# 4. release the pretrained dict for saving memory
pretrained_dict = []
model = model.eval() # deploy mode
frames_dir = args.frame_input_dir
output_dir = args.frame_output_dir
timestep = args.time_step
time_offsets = [kk * timestep for kk in range(1, int(1.0 / timestep))]
input_frame = args.start_frame - 1
loop_timer = AverageMeter()
final_frame = args.end_frame
torch.set_grad_enabled(False)
# we want to have input_frame between (start_frame-1) and (end_frame-2)
# this is because at each step we read (frame) and (frame+1)
# so the last iteration will actuall be (end_frame-1) and (end_frame)
while input_frame < final_frame - 1:
input_frame += 1
start_time = time.time()
filename_frame_1 = os.path.join(frames_dir, f'{input_frame:0>5d}.png')
filename_frame_2 = os.path.join(frames_dir, f'{input_frame+1:0>5d}.png')
X0 = torch.from_numpy(np.transpose(imread(filename_frame_1), (2,0,1)).astype("float32") / 255.0).type(args.dtype)
X1 = torch.from_numpy(np.transpose(imread(filename_frame_2), (2,0,1)).astype("float32") / 255.0).type(args.dtype)
assert (X0.size(1) == X1.size(1))
assert (X0.size(2) == X1.size(2))
intWidth = X0.size(2)
intHeight = X0.size(1)
channels = X0.size(0)
if not channels == 3:
print(f"Skipping {filename_frame_1}-{filename_frame_2} -- expected 3 color channels but found {channels}.")
continue
if intWidth != ((intWidth >> 7) << 7):
intWidth_pad = (((intWidth >> 7) + 1) << 7) # more than necessary
intPaddingLeft = int((intWidth_pad - intWidth) / 2)
intPaddingRight = intWidth_pad - intWidth - intPaddingLeft
else:
intPaddingLeft = 32
intPaddingRight= 32
if intHeight != ((intHeight >> 7) << 7):
intHeight_pad = (((intHeight >> 7) + 1) << 7) # more than necessary
intPaddingTop = int((intHeight_pad - intHeight) / 2)
intPaddingBottom = intHeight_pad - intHeight - intPaddingTop
else:
intPaddingTop = 32
intPaddingBottom = 32
pader = torch.nn.ReplicationPad2d([intPaddingLeft, intPaddingRight, intPaddingTop, intPaddingBottom])
X0 = Variable(torch.unsqueeze(X0,0))
X1 = Variable(torch.unsqueeze(X1,0))
X0 = pader(X0)
X1 = pader(X1)
if args.use_cuda:
X0 = X0.cuda()
X1 = X1.cuda()
y_s, offset, filter = model(torch.stack((X0, X1),dim = 0))
y_ = y_s[args.save_which]
if args.use_cuda:
X0 = X0.data.cpu().numpy()
if not isinstance(y_, list):
y_ = y_.data.cpu().numpy()
else:
y_ = [item.data.cpu().numpy() for item in y_]
offset = [offset_i.data.cpu().numpy() for offset_i in offset]
filter = [filter_i.data.cpu().numpy() for filter_i in filter] if filter[0] is not None else None
X1 = X1.data.cpu().numpy()
else:
X0 = X0.data.numpy()
if not isinstance(y_, list):
y_ = y_.data.numpy()
else:
y_ = [item.data.numpy() for item in y_]
offset = [offset_i.data.numpy() for offset_i in offset]
filter = [filter_i.data.numpy() for filter_i in filter]
X1 = X1.data.numpy()
X0 = np.transpose(255.0 * X0.clip(0,1.0)[0, :, intPaddingTop:intPaddingTop+intHeight, intPaddingLeft: intPaddingLeft+intWidth], (1, 2, 0))
y_ = [np.transpose(255.0 * item.clip(0,1.0)[0, :, intPaddingTop:intPaddingTop+intHeight,
intPaddingLeft:intPaddingLeft+intWidth], (1, 2, 0)) for item in y_]
offset = [np.transpose(offset_i[0, :, intPaddingTop:intPaddingTop+intHeight, intPaddingLeft: intPaddingLeft+intWidth], (1, 2, 0)) for offset_i in offset]
filter = [np.transpose(
filter_i[0, :, intPaddingTop:intPaddingTop + intHeight, intPaddingLeft: intPaddingLeft + intWidth],
(1, 2, 0)) for filter_i in filter] if filter is not None else None
X1 = np.transpose(255.0 * X1.clip(0,1.0)[0, :, intPaddingTop:intPaddingTop+intHeight, intPaddingLeft: intPaddingLeft+intWidth], (1, 2, 0))
interpolated_frame_number = 0
shutil.copy(filename_frame_1, os.path.join(output_dir, f"{input_frame:0>5d}{interpolated_frame_number:0>3d}.png"))
for item, time_offset in zip(y_, time_offsets):
interpolated_frame_number += 1
output_frame_file_path = os.path.join(output_dir, f"{input_frame:0>5d}{interpolated_frame_number:0>3d}.png")
imsave(output_frame_file_path, np.round(item).astype(numpy.uint8))
end_time = time.time()
loop_timer.update(end_time - start_time)
frames_left = final_frame - input_frame
estimated_seconds_left = frames_left * loop_timer.avg
estimated_time_left = datetime.timedelta(seconds=estimated_seconds_left)
print(f"****** Processed frame {input_frame} | Time per frame (avg): {loop_timer.avg:2.2f}s | Time left: {estimated_time_left} ******************" )
# Copying last frame
last_frame_filename = os.path.join(frames_dir, str(str(final_frame).zfill(5))+'.png')
shutil.copy(last_frame_filename, os.path.join(output_dir, f"{final_frame:0>5d}{0:0>3d}.png"))
print("Finished processing images.")