from torch.cuda.amp import autocast from models.steps.losses import ConfigurableLoss, GANLoss, extract_params_from_state, get_basic_criterion_for_name from models.flownet2.networks.resample2d_package.resample2d import Resample2d from models.steps.injectors import Injector import torch import torch.nn.functional as F import os import os.path as osp import torchvision import torch.distributed as dist def create_teco_loss(opt, env): type = opt['type'] if type == 'teco_gan': return TecoGanLoss(opt, env) elif type == "teco_pingpong": return PingPongLoss(opt, env) return None def create_teco_injector(opt, env): type = opt['type'] if type == 'teco_recurrent_generated_sequence_injector': return RecurrentImageGeneratorSequenceInjector(opt, env) elif type == 'teco_flow_adjustment': return FlowAdjustment(opt, env) return None def create_teco_discriminator_sextuplet(input_list, lr_imgs, scale, index, flow_gen, resampler, margin): # Flow is interpreted from the LR images so that the generator cannot learn to manipulate it. with autocast(enabled=False): triplet = input_list[:, index:index+3].float() first_flow = flow_gen(torch.stack([triplet[:,1], triplet[:,0]], dim=2)) last_flow = flow_gen(torch.stack([triplet[:,1], triplet[:,2]], dim=2)) flow_triplet = [resampler(triplet[:,0], first_flow), triplet[:,1], resampler(triplet[:,2], last_flow)] flow_triplet = torch.stack(flow_triplet, dim=1) combined = torch.cat([triplet, flow_triplet], dim=1) b, f, c, h, w = combined.shape combined = combined.view(b, 3*6, h, w) # 3*6 is essentially an assertion here. # Apply margin return combined[:, :, margin:-margin, margin:-margin] def extract_inputs_index(inputs, i): res = [] for input in inputs: if isinstance(input, torch.Tensor): res.append(input[:, i]) else: res.append(input) return res # Uses a generator to synthesize a sequence of images from [in] and injects the results into a list [out] # Images are fed in sequentially forward and back, resulting in len([out])=2*len([in])-1 (last element is not repeated). # All computation is done with torch.no_grad(). class RecurrentImageGeneratorSequenceInjector(Injector): def __init__(self, opt, env): super(RecurrentImageGeneratorSequenceInjector, self).__init__(opt, env) self.flow = opt['flow_network'] self.input_lq_index = opt['input_lq_index'] if 'input_lq_index' in opt.keys() else 0 self.output_hq_index = opt['output_hq_index'] if 'output_hq_index' in opt.keys() else 0 self.recurrent_index = opt['recurrent_index'] self.scale = opt['scale'] self.resample = Resample2d() self.first_inputs = opt['first_inputs'] if 'first_inputs' in opt.keys() else opt['in'] # Use this to specify inputs that will be used in the first teco iteration, the rest will use 'in'. self.do_backwards = opt['do_backwards'] if 'do_backwards' in opt.keys() else True self.hq_recurrent = opt['hq_recurrent'] if 'hq_recurrent' in opt.keys() else False # When True, recurrent_index is not touched for the first iteration, allowing you to specify what is fed in. When False, zeros are fed into the recurrent index. def forward(self, state): gen = self.env['generators'][self.opt['generator']] flow = self.env['generators'][self.flow] first_inputs = extract_params_from_state(self.first_inputs, state) inputs = extract_params_from_state(self.input, state) if not isinstance(inputs, list): inputs = [inputs] if not isinstance(self.output, list): self.output = [self.output] results = {} for out_key in self.output: results[out_key] = [] # Go forward in the sequence first. first_step = True b, f, c, h, w = inputs[self.input_lq_index].shape debug_index = 0 for i in range(f): if first_step: input = extract_inputs_index(first_inputs, i) if self.hq_recurrent: recurrent_input = input[self.recurrent_index] else: recurrent_input = torch.zeros_like(input[self.recurrent_index]) first_step = False else: input = extract_inputs_index(inputs, i) with torch.no_grad() and autocast(enabled=False): reduced_recurrent = F.interpolate(recurrent_input, scale_factor=1/self.scale, mode='bicubic') flow_input = torch.stack([input[self.input_lq_index], reduced_recurrent], dim=2).float() flowfield = F.interpolate(flow(flow_input), scale_factor=self.scale, mode='bicubic') recurrent_input = self.resample(recurrent_input.float(), flowfield) input[self.recurrent_index] = recurrent_input if self.env['step'] % 50 == 0: self.produce_teco_visual_debugs(input[self.input_lq_index], input[self.recurrent_index], debug_index) debug_index += 1 with autocast(enabled=self.env['opt']['fp16']): gen_out = gen(*input) if isinstance(gen_out, torch.Tensor): gen_out = [gen_out] for i, out_key in enumerate(self.output): results[out_key].append(gen_out[i]) recurrent_input = gen_out[self.output_hq_index] # Now go backwards, skipping the last element (it's already stored in recurrent_input) if self.do_backwards: it = reversed(range(f - 1)) for i in it: input = extract_inputs_index(inputs, i) with torch.no_grad(): with autocast(enabled=False): reduced_recurrent = F.interpolate(recurrent_input, scale_factor=1 / self.scale, mode='bicubic') flow_input = torch.stack([input[self.input_lq_index], reduced_recurrent], dim=2).float() flowfield = F.interpolate(flow(flow_input), scale_factor=self.scale, mode='bicubic') recurrent_input = self.resample(recurrent_input.float(), flowfield) input[self.recurrent_index] = recurrent_input if self.env['step'] % 50 == 0: self.produce_teco_visual_debugs(input[self.input_lq_index], input[self.recurrent_index], debug_index) debug_index += 1 with autocast(enabled=self.env['opt']['fp16']): gen_out = gen(*input) if isinstance(gen_out, torch.Tensor): gen_out = [gen_out] for i, out_key in enumerate(self.output): results[out_key].append(gen_out[i]) recurrent_input = gen_out[self.output_hq_index] for k, v in results.items(): results[k] = torch.stack(v, dim=1) return results def produce_teco_visual_debugs(self, gen_input, gen_recurrent, it): if self.env['rank'] > 0: return base_path = osp.join(self.env['base_path'], "..", "visual_dbg", "teco_geninput", str(self.env['step'])) os.makedirs(base_path, exist_ok=True) torchvision.utils.save_image(gen_input.float(), osp.join(base_path, "%s_img.png" % (it,))) torchvision.utils.save_image(gen_recurrent.float(), osp.join(base_path, "%s_recurrent.png" % (it,))) class FlowAdjustment(Injector): def __init__(self, opt, env): super(FlowAdjustment, self).__init__(opt, env) self.resample = Resample2d() self.flow = opt['flow_network'] self.flow_target = opt['flow_target'] self.flowed = opt['flowed'] def forward(self, state): with autocast(enabled=False): flow = self.env['generators'][self.flow] flow_target = state[self.flow_target] flowed = F.interpolate(state[self.flowed], size=flow_target.shape[2:], mode='bicubic') flow_input = torch.stack([flow_target, flowed], dim=2).float() flowfield = F.interpolate(flow(flow_input), size=state[self.flowed].shape[2:], mode='bicubic') return {self.output: self.resample(state[self.flowed], flowfield)} # This is the temporal discriminator loss from TecoGAN. # # It has a strict contract for 'real' and 'fake' inputs: # 'real' - Must be a list of arbitrary images (len>3) drawn from the dataset # 'fake' - The output of the RecurrentImageGeneratorSequenceInjector for the same set of images. # # This loss does the following: # 1) Picks an image triplet, starting with the first '3' elements in 'real' and 'fake'. # 2) Uses the image flow generator (specified with 'image_flow_generator') to create detached flow fields for the first and last images in the above sequence. # 3) Warps the first and last images according to the flow field. # 4) Composes the three base image and the 2 warped images and middle image into a tensor concatenated at the filter dimension for both real and fake, resulting in a bx18xhxw shape tensor. # 5) Feeds the catted real and fake image sets into the discriminator, computes a loss, and backward(). # 6) Repeat from (1) until all triplets from the real sequence have been exhausted. class TecoGanLoss(ConfigurableLoss): def __init__(self, opt, env): super(TecoGanLoss, self).__init__(opt, env) self.criterion = GANLoss(opt['gan_type'], 1.0, 0.0).to(env['device']) # TecoGAN parameters self.scale = opt['scale'] self.lr_inputs = opt['lr_inputs'] self.image_flow_generator = opt['image_flow_generator'] self.resampler = Resample2d() self.for_generator = opt['for_generator'] self.min_loss = opt['min_loss'] if 'min_loss' in opt.keys() else 0 self.margin = opt['margin'] # Per the tecogan paper, the GAN loss only pays attention to an inner part of the image with the margin removed, to get rid of artifacts resulting from flow errors. def forward(self, _, state): fp16 = self.env['opt']['fp16'] net = self.env['discriminators'][self.opt['discriminator']] flow_gen = self.env['generators'][self.image_flow_generator] real = state[self.opt['real']] fake = state[self.opt['fake']] sequence_len = real.shape[1] lr = state[self.opt['lr_inputs']] l_total = 0 for i in range(sequence_len - 2): real_sext = create_teco_discriminator_sextuplet(real, lr, self.scale, i, flow_gen, self.resampler, self.margin) fake_sext = create_teco_discriminator_sextuplet(fake, lr, self.scale, i, flow_gen, self.resampler, self.margin) with autocast(enabled=fp16): d_fake = net(fake_sext) d_real = net(real_sext) self.metrics.append(("d_fake", torch.mean(d_fake))) self.metrics.append(("d_real", torch.mean(d_real))) if self.for_generator and self.env['step'] % 50 == 0: self.produce_teco_visual_debugs(fake_sext, 'fake', i) self.produce_teco_visual_debugs(real_sext, 'real', i) if self.opt['gan_type'] in ['gan', 'pixgan']: l_fake = self.criterion(d_fake, self.for_generator) if not self.for_generator: l_real = self.criterion(d_real, True) else: l_real = 0 l_step = l_fake + l_real elif self.opt['gan_type'] == 'ragan': d_fake_diff = d_fake - torch.mean(d_real) self.metrics.append(("d_fake_diff", torch.mean(d_fake_diff))) l_step = (self.criterion(d_real - torch.mean(d_fake), not self.for_generator) + self.criterion(d_fake_diff, self.for_generator)) else: raise NotImplementedError if l_step > self.min_loss: l_total += l_step return l_total def produce_teco_visual_debugs(self, sext, lbl, it): if self.env['rank'] > 0: return base_path = osp.join(self.env['base_path'], "..", "visual_dbg", "teco_sext", str(self.env['step']), lbl) os.makedirs(base_path, exist_ok=True) lbls = ['img_a', 'img_b', 'img_c', 'flow_a', 'flow_b', 'flow_c'] for i in range(6): torchvision.utils.save_image(sext[:, i*3:(i+1)*3, :, :].float(), osp.join(base_path, "%s_%s.png" % (it, lbls[i]))) # This loss doesn't have a real entry - only fakes are used. class PingPongLoss(ConfigurableLoss): def __init__(self, opt, env): super(PingPongLoss, self).__init__(opt, env) self.opt = opt self.criterion = get_basic_criterion_for_name(opt['criterion'], env['device']) def forward(self, _, state): fake = state[self.opt['fake']] l_total = 0 img_count = fake.shape[1] for i in range((img_count - 1) // 2): early = fake[:, i] late = fake[:, -i] l_total += self.criterion(early, late) if self.env['step'] % 50 == 0: self.produce_teco_visual_debugs(fake) return l_total def produce_teco_visual_debugs(self, imglist): if self.env['rank'] > 0: return base_path = osp.join(self.env['base_path'], "..", "visual_dbg", "teco_pingpong", str(self.env['step'])) os.makedirs(base_path, exist_ok=True) cnt = imglist.shape[1] for i in range(cnt): img = imglist[:, i] torchvision.utils.save_image(img.float(), osp.join(base_path, "%s.png" % (i, )))