import copy import logging import os from time import time import torch from torch.nn.parallel import DataParallel import torch.nn as nn import trainer.lr_scheduler as lr_scheduler import trainer.networks as networks from trainer.base_model import BaseModel from trainer.batch_size_optimizer import create_batch_size_optimizer from trainer.inject import create_injector from trainer.steps import ConfigurableStep from trainer.experiments.experiments import get_experiment_for_name import torchvision.utils as utils from utils.loss_accumulator import LossAccumulator, InfStorageLossAccumulator from utils.util import opt_get, denormalize logger = logging.getLogger('base') # State is immutable to reduce complexity. Overwriting existing state keys is not supported. class OverwrittenStateError(Exception): def __init__(self, k, keys): super().__init__(f'Attempted to overwrite state key: {k}. The state should be considered ' f'immutable and keys should not be overwritten. Current keys: {keys}') class ExtensibleTrainer(BaseModel): def __init__(self, opt, cached_networks={}): super(ExtensibleTrainer, self).__init__(opt) if opt['dist']: self.rank = torch.distributed.get_rank() else: self.rank = -1 # non dist training train_opt = opt['train'] # env is used as a global state to store things that subcomponents might need. self.env = {'device': self.device, 'rank': self.rank, 'opt': opt, 'step': 0, 'dist': opt['dist'] } if opt['path']['models'] is not None: self.env['base_path'] = os.path.join(opt['path']['models']) self.mega_batch_factor = 1 if self.is_train: self.mega_batch_factor = train_opt['mega_batch_factor'] self.env['mega_batch_factor'] = self.mega_batch_factor self.batch_factor = self.mega_batch_factor self.ema_rate = opt_get(train_opt, ['ema_rate'], .999) # It is advantageous for large networks to do this to save an extra copy of the model weights. # It does come at the cost of a round trip to CPU memory at every batch. self.do_emas = opt_get(train_opt, ['ema_enabled'], True) self.ema_on_cpu = opt_get(train_opt, ['ema_on_cpu'], False) self.checkpointing_cache = opt['checkpointing_enabled'] self.auto_recover = opt_get(opt, ['automatically_recover_nan_by_reverting_n_saves'], None) self.batch_size_optimizer = create_batch_size_optimizer(train_opt) self.netsG = {} self.netsD = {} for name, net in opt['networks'].items(): # Trainable is a required parameter, but the default is simply true. Set it here. if 'trainable' not in net.keys(): net['trainable'] = True if name in cached_networks.keys(): new_net = cached_networks[name] else: new_net = None if net['type'] == 'generator': if new_net is None: new_net = networks.create_model(opt, net, self.netsG).to(self.device) self.netsG[name] = new_net elif net['type'] == 'discriminator': if new_net is None: new_net = networks.create_model(opt, net, self.netsD).to(self.device) self.netsD[name] = new_net else: raise NotImplementedError("Can only handle generators and discriminators") if not net['trainable']: new_net.eval() if net['wandb_debug'] and self.rank <= 0: import wandb wandb.watch(new_net, log='all', log_freq=3) # Initialize the train/eval steps self.step_names = [] self.steps = [] for step_name, step in opt['steps'].items(): step = ConfigurableStep(step, self.env) self.step_names.append(step_name) # This could be an OrderedDict, but it's a PITA to integrate with AMP below. self.steps.append(step) # step.define_optimizers() relies on the networks being placed in the env, so put them there. Even though # they aren't wrapped yet. self.env['generators'] = self.netsG self.env['discriminators'] = self.netsD # Define the optimizers from the steps for s in self.steps: s.define_optimizers() self.optimizers.extend(s.get_optimizers()) if self.is_train: # Find the optimizers that are using the default scheduler, then build them. def_opt = [] for s in self.steps: def_opt.extend(s.get_optimizers_with_default_scheduler()) self.schedulers = lr_scheduler.get_scheduler_for_name(train_opt['default_lr_scheme'], def_opt, train_opt) # Set the starting step count for the scheduler. for sched in self.schedulers: sched.last_epoch = opt['current_step'] else: self.schedulers = [] # Wrap networks in distributed shells. dnets = [] all_networks = [g for g in self.netsG.values()] + [d for d in self.netsD.values()] for anet in all_networks: has_any_trainable_params = False for p in anet.parameters(): if not hasattr(p, 'DO_NOT_TRAIN'): has_any_trainable_params = True break if has_any_trainable_params and opt['dist']: if opt['dist_backend'] == 'apex': # Use Apex to enable delay_allreduce, which is compatible with gradient checkpointing. from apex.parallel import DistributedDataParallel dnet = DistributedDataParallel(anet, delay_allreduce=True) else: from torch.nn.parallel.distributed import DistributedDataParallel # Do NOT be tempted to put find_unused_parameters=True here. It will not work when checkpointing is # used and in a few other cases. But you can try it if you really want. dnet = DistributedDataParallel(anet, device_ids=[torch.cuda.current_device()], find_unused_parameters=opt_get(opt, ['ddp_find_unused_parameters'], False)) # DDP graphs cannot be used with gradient checkpointing unless you use find_unused_parameters=True, # which does not work with this trainer (as stated above). However, if the graph is not subject # to control flow alterations, you can set this option to allow gradient checkpointing. Beware that # if you are wrong about control flow, DDP will not train all your model parameters! User beware! if opt_get(opt, ['ddp_static_graph'], False): dnet._set_static_graph() else: dnet = DataParallel(anet, device_ids=[torch.cuda.current_device()]) if self.is_train: dnet.train() else: dnet.eval() dnets.append(dnet) # Backpush the wrapped networks into the network dicts. Also build the EMA parameters. self.networks = {} self.emas = {} found = 0 for dnet in dnets: for net_dict in [self.netsD, self.netsG]: for k, v in net_dict.items(): if v == dnet.module: net_dict[k] = dnet self.networks[k] = dnet if self.is_train and self.do_emas: self.emas[k] = copy.deepcopy(v) if self.ema_on_cpu: self.emas[k] = self.emas[k].cpu() found += 1 assert found == len(self.netsG) + len(self.netsD) # Replace the env networks with the wrapped networks self.env['generators'] = self.netsG self.env['discriminators'] = self.netsD self.env['emas'] = self.emas self.print_network() # print network self.load() # load networks from save states as needed # Load experiments self.experiments = [] if 'experiments' in opt.keys(): self.experiments = [get_experiment_for_name(e) for e in opt['experiments']] # Setting this to false triggers SRGAN to call the models update_model() function on the first iteration. self.updated = True def feed_data(self, data, step, need_GT=True, perform_micro_batching=True): self.env['step'] = step self.batch_factor = self.mega_batch_factor self.opt['checkpointing_enabled'] = self.checkpointing_cache # The batch factor can be adjusted on a period to allow known high-memory steps to fit in GPU memory. if 'train' in self.opt.keys() and \ 'mod_batch_factor' in self.opt['train'].keys() and \ self.env['step'] % self.opt['train']['mod_batch_factor_every'] == 0: self.batch_factor = self.opt['train']['mod_batch_factor'] if self.opt['train']['mod_batch_factor_also_disable_checkpointing']: self.opt['checkpointing_enabled'] = False self.eval_state = {} for o in self.optimizers: o.zero_grad() torch.cuda.empty_cache() sort_key = opt_get(self.opt, ['train', 'sort_key'], None) if sort_key is not None: sort_indices = torch.sort(data[sort_key], descending=True).indices else: sort_indices = None batch_factor = self.batch_factor if perform_micro_batching else 1 self.dstate = {} for k, v in data.items(): if sort_indices is not None: if isinstance(v, list): v = [v[i] for i in sort_indices] else: v = v[sort_indices] if isinstance(v, torch.Tensor): self.dstate[k] = [t.to(self.device) for t in torch.chunk(v, chunks=batch_factor, dim=0)] if opt_get(self.opt, ['train', 'auto_collate'], False): for k, v in self.dstate.items(): if f'{k}_lengths' in self.dstate.keys(): for c in range(len(v)): maxlen = self.dstate[f'{k}_lengths'][c].max() if len(v[c].shape) == 2: self.dstate[k][c] = self.dstate[k][c][:, :maxlen] elif len(v[c].shape) == 3: self.dstate[k][c] = self.dstate[k][c][:, :, :maxlen] elif len(v[c].shape) == 4: self.dstate[k][c] = self.dstate[k][c][:, :, :, :maxlen] def optimize_parameters(self, it, optimize=True, return_grad_norms=False): grad_norms = {} # Some models need to make parametric adjustments per-step. Do that here. for net in self.networks.values(): if hasattr(net.module, "update_for_step"): net.module.update_for_step(it, os.path.join(self.opt['path']['models'], "..")) # Iterate through the steps, performing them one at a time. state = self.dstate for step_num, step in enumerate(self.steps): train_step = True # 'every' is used to denote steps that should only occur at a certain integer factor rate. e.g. '2' occurs every 2 steps. # Note that the injection points for the step might still be required, so address this by setting train_step=False if 'every' in step.step_opt.keys() and it % step.step_opt['every'] != 0: train_step = False # Steps can opt out of early (or late) training, make sure that happens here. if 'after' in step.step_opt.keys() and it < step.step_opt['after'] or 'before' in step.step_opt.keys() and it > step.step_opt['before']: continue # Steps can choose to not execute if a state key is missing. if 'requires' in step.step_opt.keys(): requirements_met = True for requirement in step.step_opt['requires']: if requirement not in state.keys(): requirements_met = False if not requirements_met: continue if train_step: # Only set requires_grad=True for the network being trained. nets_to_train = step.get_networks_trained() enabled = 0 for name, net in self.networks.items(): net_enabled = name in nets_to_train if net_enabled: enabled += 1 # Networks can opt out of training before a certain iteration by declaring 'after' in their definition. if 'after' in self.opt['networks'][name].keys() and it < self.opt['networks'][name]['after']: net_enabled = False for p in net.parameters(): do_not_train_flag = hasattr(p, "DO_NOT_TRAIN") or (hasattr(p, "DO_NOT_TRAIN_UNTIL") and it < p.DO_NOT_TRAIN_UNTIL) if p.dtype != torch.int64 and p.dtype != torch.bool and not do_not_train_flag: p.requires_grad = net_enabled else: p.requires_grad = False assert enabled == len(nets_to_train) # Update experiments [e.before_step(self.opt, self.step_names[step_num], self.env, nets_to_train, state) for e in self.experiments] for o in step.get_optimizers(): o.zero_grad() # Now do a forward and backward pass for each gradient accumulation step. new_states = {} self.batch_size_optimizer.focus(net) for m in range(self.batch_factor): ns = step.do_forward_backward(state, m, step_num, train=train_step, no_ddp_sync=(m+1 < self.batch_factor)) for k, v in ns.items(): if k not in new_states.keys(): new_states[k] = [v] else: new_states[k].append(v) # Push the detached new state tensors into the state map for use with the next step. for k, v in new_states.items(): if k in state.keys(): raise OverwrittenStateError(k, list(state.keys())) state[k] = v if return_grad_norms and train_step: for name in nets_to_train: model = self.networks[name] if hasattr(model.module, 'get_grad_norm_parameter_groups'): pgroups = {f'{name}_{k}': v for k, v in model.module.get_grad_norm_parameter_groups().items()} else: pgroups = {f'{name}_all_parameters': list(model.parameters())} for name in pgroups.keys(): grad_norms[name] = torch.norm(torch.stack([torch.norm(p.grad.detach(), 2) for p in pgroups[name]]), 2) # (Maybe) perform a step. if train_step and optimize and self.batch_size_optimizer.should_step(it): self.consume_gradients(state, step, it) # Record visual outputs for usage in debugging and testing. if 'visuals' in self.opt['logger'].keys() and self.rank <= 0 and it % self.opt['logger']['visual_debug_rate'] == 0: def fix_image(img): if opt_get(self.opt, ['logger', 'is_mel_spectrogram'], False): img = img.unsqueeze(dim=1) # Normalize so spectrogram is easier to view. img = (img - img.mean()) / img.std() if img.shape[1] > 3: img = img[:, :3, :, :] if opt_get(self.opt, ['logger', 'reverse_n1_to_1'], False): img = (img + 1) / 2 if opt_get(self.opt, ['logger', 'reverse_imagenet_norm'], False): img = denormalize(img) return img sample_save_path = os.path.join(self.opt['path']['models'], "..", "visual_dbg") for v in self.opt['logger']['visuals']: if v not in state.keys(): continue # This can happen for several reasons (ex: 'after' defs), just ignore it. for i, dbgv in enumerate(state[v]): if 'recurrent_visual_indices' in self.opt['logger'].keys() and len(dbgv.shape)==5: for rvi in self.opt['logger']['recurrent_visual_indices']: rdbgv = fix_image(dbgv[:, rvi]) os.makedirs(os.path.join(sample_save_path, v), exist_ok=True) utils.save_image(rdbgv.float(), os.path.join(sample_save_path, v, "%05i_%02i_%02i.png" % (it, rvi, i))) else: dbgv = fix_image(dbgv) os.makedirs(os.path.join(sample_save_path, v), exist_ok=True) utils.save_image(dbgv.float(), os.path.join(sample_save_path, v, "%05i_%02i.png" % (it, i))) # Some models have their own specific visual debug routines. for net_name, net in self.networks.items(): if hasattr(net.module, "visual_dbg"): model_vdbg_dir = os.path.join(sample_save_path, net_name) os.makedirs(model_vdbg_dir, exist_ok=True) net.module.visual_dbg(it, model_vdbg_dir) return grad_norms def consume_gradients(self, state, step, it): [e.before_optimize(state) for e in self.experiments] step.do_step(it) # Call into custom step hooks as well as update EMA params. for name, net in self.networks.items(): if hasattr(net, "custom_optimizer_step"): net.custom_optimizer_step(it) if self.do_emas: ema_params = self.emas[name].parameters() net_params = net.parameters() for ep, np in zip(ema_params, net_params): if self.ema_on_cpu: np = np.cpu() ep.detach().mul_(self.ema_rate).add_(np, alpha=1 - self.ema_rate) [e.after_optimize(state) for e in self.experiments] def test(self): for net in self.netsG.values(): net.eval() accum_metrics = InfStorageLossAccumulator() with torch.no_grad(): # This can happen one of two ways: Either a 'validation injector' is provided, in which case we run that. # Or, we run the entire chain of steps in "train" mode and use eval.output_state. if 'injectors' in self.opt['eval'].keys(): state = {} for inj in self.opt['eval']['injectors'].values(): # Need to move from mega_batch mode to batch mode (remove chunks) for k, v in self.dstate.items(): state[k] = v[0] inj = create_injector(inj, self.env) state.update(inj(state)) else: # Iterate through the steps, performing them one at a time. state = self.dstate for step_num, s in enumerate(self.steps): ns = s.do_forward_backward(state, 0, step_num, train=False, loss_accumulator=accum_metrics) for k, v in ns.items(): state[k] = [v] self.eval_state = {} for k, v in state.items(): if isinstance(v, list): self.eval_state[k] = [s.detach().cpu() if isinstance(s, torch.Tensor) else s for s in v] else: self.eval_state[k] = [v.detach().cpu() if isinstance(v, torch.Tensor) else v] for net in self.netsG.values(): net.train() return accum_metrics # Fetches a summary of the log. def get_current_log(self, step): log = {} for s in self.steps: log.update(s.get_metrics()) for e in self.experiments: log.update(e.get_log_data()) # Some generators can do their own metric logging. for net_name, net in self.networks.items(): if hasattr(net.module, "get_debug_values"): log.update(net.module.get_debug_values(step, net_name)) # Log learning rate (from first param group) too. for o in self.optimizers: for pgi, pg in enumerate(o.param_groups): log['learning_rate_%s_%i' % (o._config['network'], pgi)] = pg['lr'] # The batch size optimizer also outputs loggable data. log.update(self.batch_size_optimizer.get_statistics()) return log def get_current_visuals(self, need_GT=True): # Conforms to an archaic format from MMSR. res = {'rlt': self.eval_state[self.opt['eval']['output_state']][0].float().cpu()} if 'hq' in self.eval_state.keys(): res['hq'] = self.eval_state['hq'][0].float().cpu(), return res def print_network(self): for name, net in self.networks.items(): s, n = self.get_network_description(net) net_struc_str = '{}'.format(net.__class__.__name__) if self.rank <= 0: logger.info('Network {} structure: {}, with parameters: {:,d}'.format(name, net_struc_str, n)) logger.info(s) def load(self): for netdict in [self.netsG, self.netsD]: for name, net in netdict.items(): load_path = self.opt['path']['pretrain_model_%s' % (name,)] if load_path is None: return if self.rank <= 0: logger.info('Loading model for [%s]' % (load_path,)) self.load_network(load_path, net, self.opt['path']['strict_load'], opt_get(self.opt, ['path', f'pretrain_base_path_{name}'])) load_path_ema = load_path.replace('.pth', '_ema.pth') if self.is_train and self.do_emas: ema_model = self.emas[name] if os.path.exists(load_path_ema): self.load_network(load_path_ema, ema_model, self.opt['path']['strict_load'], opt_get(self.opt, ['path', f'pretrain_base_path_{name}'])) else: print("WARNING! Unable to find EMA network! Starting a new EMA from given model parameters.") self.emas[name] = copy.deepcopy(net) if self.ema_on_cpu: self.emas[name] = self.emas[name].cpu() if hasattr(net.module, 'network_loaded'): net.module.network_loaded() def save(self, iter_step): for name, net in self.networks.items(): # Don't save non-trainable networks. if self.opt['networks'][name]['trainable']: self.save_network(net, name, iter_step) if self.do_emas: self.save_network(self.emas[name], f'{name}_ema', iter_step) def force_restore_swapout(self): # Legacy method. Do nothing. pass