# This module is modified from https://github.com/Plachtaa/VALL-E-X/blob/3faaf8ccadb154d63b38070caf518ce9309ea0f4/modules/optim.py#L836 import logging import contextlib import torch from torch import Tensor from torch.optim.lr_scheduler import _LRScheduler from torch.optim import Optimizer from typing import List, Tuple from collections import defaultdict class NoamLR(_LRScheduler): """ Implements the Noam Learning rate schedule. This corresponds to increasing the learning rate linearly for the first ``num_warmup`` training steps, and decreasing it thereafter proportionally to the inverse square root of the step number, scaled by the inverse square root of the dimensionality of the model. Time will tell if this is just madness or it's actually important. Parameters ---------- num_warmup: ``int``, required. The number of steps to linearly increase the learning rate. """ def __init__(self, optimizer, num_warmup): self.num_warmup = num_warmup self.base_lr = optimizer.param_groups[0]["lr"] super().__init__(optimizer) def get_lr(self): last_epoch = max(1, self.last_epoch) scale = min(last_epoch ** (-0.5), last_epoch * self.num_warmup ** (-1.5)) return [scale * self.base_lr] class Eve(Optimizer): """ Implements Eve algorithm. This is a modified version of AdamW with a special way of setting the weight-decay / shrinkage-factor, which is designed to make the rms of the parameters approach a particular target_rms (default: 0.1). This is for use with networks with 'scaled' versions of modules (see scaling.py), which will be close to invariant to the absolute scale on the parameter matrix. The original Adam algorithm was proposed in `Adam: A Method for Stochastic Optimization`_. The AdamW variant was proposed in `Decoupled Weight Decay Regularization`_. Eve is unpublished so far. Arguments: params (iterable): iterable of parameters to optimize or dicts defining parameter groups lr (float, optional): learning rate (default: 1e-3) betas (Tuple[float, float], optional): coefficients used for computing running averages of gradient and its square (default: (0.9, 0.999)) eps (float, optional): term added to the denominator to improve numerical stability (default: 1e-8) weight_decay (float, optional): weight decay coefficient (default: 3e-4; this value means that the weight would decay significantly after about 3k minibatches. Is not multiplied by learning rate, but is conditional on RMS-value of parameter being > target_rms. target_rms (float, optional): target root-mean-square value of parameters, if they fall below this we will stop applying weight decay. .. _Adam: A Method for Stochastic Optimization: https://arxiv.org/abs/1412.6980 .. _Decoupled Weight Decay Regularization: https://arxiv.org/abs/1711.05101 .. _On the Convergence of Adam and Beyond: https://openreview.net/forum?id=ryQu7f-RZ """ def __init__( self, params, lr=1e-3, betas=(0.9, 0.98), eps=1e-8, weight_decay=1e-3, target_rms=0.1, ): if not 0.0 <= lr: raise ValueError("Invalid learning rate: {}".format(lr)) if not 0.0 <= eps: raise ValueError("Invalid epsilon value: {}".format(eps)) if not 0.0 <= betas[0] < 1.0: raise ValueError("Invalid beta parameter at index 0: {}".format(betas[0])) if not 0.0 <= betas[1] < 1.0: raise ValueError("Invalid beta parameter at index 1: {}".format(betas[1])) if not 0 <= weight_decay <= 0.1: raise ValueError("Invalid weight_decay value: {}".format(weight_decay)) if not 0 < target_rms <= 10.0: raise ValueError("Invalid target_rms value: {}".format(target_rms)) defaults = dict( lr=lr, betas=betas, eps=eps, weight_decay=weight_decay, target_rms=target_rms, ) super(Eve, self).__init__(params, defaults) def __setstate__(self, state): super(Eve, self).__setstate__(state) @torch.no_grad() def step(self, closure=None): """Performs a single optimization step. Arguments: closure (callable, optional): A closure that reevaluates the model and returns the loss. """ loss = None if closure is not None: with torch.enable_grad(): loss = closure() for group in self.param_groups: for p in group["params"]: if p.grad is None: continue # Perform optimization step grad = p.grad if grad.is_sparse: raise RuntimeError("AdamW does not support sparse gradients") state = self.state[p] # State initialization if len(state) == 0: state["step"] = 0 # Exponential moving average of gradient values state["exp_avg"] = torch.zeros_like( p, memory_format=torch.preserve_format ) # Exponential moving average of squared gradient values state["exp_avg_sq"] = torch.zeros_like( p, memory_format=torch.preserve_format ) exp_avg, exp_avg_sq = state["exp_avg"], state["exp_avg_sq"] beta1, beta2 = group["betas"] state["step"] += 1 bias_correction1 = 1 - beta1 ** state["step"] bias_correction2 = 1 - beta2 ** state["step"] # Decay the first and second moment running average coefficient exp_avg.mul_(beta1).add_(grad, alpha=1 - beta1) exp_avg_sq.mul_(beta2).addcmul_(grad, grad, value=1 - beta2) denom = (exp_avg_sq.sqrt() * (bias_correction2**-0.5)).add_( group["eps"] ) step_size = group["lr"] / bias_correction1 target_rms = group["target_rms"] weight_decay = group["weight_decay"] if p.numel() > 1: # avoid applying this weight-decay on "scaling factors" # (which are scalar). is_above_target_rms = p.norm() > (target_rms * (p.numel() ** 0.5)) p.mul_(1 - (weight_decay * is_above_target_rms)) p.addcdiv_(exp_avg, denom, value=-step_size) # if random.random() < 0.0005: # step = (exp_avg / denom) * step_size # logging.info( # f"Delta rms = {(step**2).mean().item()}, shape = {step.shape}" # ) return loss class BatchedOptimizer(Optimizer): """ This class adds to class Optimizer the capability to optimize parameters in batches: it will stack the parameters and their grads for you so the optimizer can work on tensors with an extra leading dimension. This is intended for speed with GPUs, as it reduces the number of kernels launched in the optimizer. Args: params: """ def __init__(self, params, defaults): super(BatchedOptimizer, self).__init__(params, defaults) @contextlib.contextmanager def batched_params(self, param_group, group_params_names): """ This function returns (technically, yields) a list of of tuples (p, state), where p is a `fake` parameter that is stacked (over axis 0) from real parameters that share the same shape, and its gradient is also stacked; `state` is the state corresponding to this batch of parameters (it will be physically located in the "state" for one of the real parameters, the last one that has any particular shape and dtype). This function is decorated as a context manager so that it can write parameters back to their "real" locations. The idea is, instead of doing: for p in group["params"]: state = self.state[p] ... you can do: with self.batched_params(group["params"]) as batches: for p, state, p_names in batches: ... Args: group: a parameter group, which is a list of parameters; should be one of self.param_groups. group_params_names: name for each parameter in group, which is List[str]. """ batches = defaultdict( list ) # `batches` maps from tuple (dtype_as_str,*shape) to list of nn.Parameter batches_names = defaultdict( list ) # `batches` maps from tuple (dtype_as_str,*shape) to list of str assert len(param_group) == len(group_params_names) for p, named_p in zip(param_group, group_params_names): key = (str(p.dtype), *p.shape) batches[key].append(p) batches_names[key].append(named_p) batches_names_keys = list(batches_names.keys()) sorted_idx = sorted( range(len(batches_names)), key=lambda i: batches_names_keys[i] ) batches_names = [batches_names[batches_names_keys[idx]] for idx in sorted_idx] batches = [batches[batches_names_keys[idx]] for idx in sorted_idx] stacked_params_dict = dict() # turn batches into a list, in deterministic order. # tuples will contain tuples of (stacked_param, state, stacked_params_names), # one for each batch in `batches`. tuples = [] for batch, batch_names in zip(batches, batches_names): p = batch[0] # we arbitrarily store the state in the # state corresponding to the 1st parameter in the # group. class Optimizer will take care of saving/loading state. state = self.state[p] p_stacked = torch.stack(batch) grad = torch.stack( [torch.zeros_like(p) if p.grad is None else p.grad for p in batch] ) p_stacked.grad = grad stacked_params_dict[key] = p_stacked tuples.append((p_stacked, state, batch_names)) yield tuples for (stacked_params, _state, _names), batch in zip(tuples, batches): for i, p in enumerate(batch): p.copy_(stacked_params[i]) class ScaledAdam(BatchedOptimizer): """ Implements 'Scaled Adam', a variant of Adam where we scale each parameter's update proportional to the norm of that parameter; and also learn the scale of the parameter, in log space, subject to upper and lower limits (as if we had factored each parameter as param = underlying_param * log_scale.exp()) Args: params: The parameters or param_groups to optimize (like other Optimizer subclasses) lr: The learning rate. We will typically use a learning rate schedule that starts at 0.03 and decreases over time, i.e. much higher than other common optimizers. clipping_scale: (e.g. 2.0) A scale for gradient-clipping: if specified, the normalized gradients over the whole model will be clipped to have 2-norm equal to `clipping_scale` times the median 2-norm over the most recent period of `clipping_update_period` minibatches. By "normalized gradients", we mean after multiplying by the rms parameter value for this tensor [for non-scalars]; this is appropriate because our update is scaled by this quantity. betas: beta1,beta2 are momentum constants for regular momentum, and moving sum-sq grad. Must satisfy 0 < beta <= beta2 < 1. scalar_lr_scale: A scaling factor on the learning rate, that we use to update the scale of each parameter tensor and scalar parameters of the mode.. If each parameter were decomposed as p * p_scale.exp(), where (p**2).mean().sqrt() == 1.0, scalar_lr_scale would be a the scaling factor on the learning rate of p_scale. eps: A general-purpose epsilon to prevent division by zero param_min_rms: Minimum root-mean-square value of parameter tensor, for purposes of learning the scale on the parameters (we'll constrain the rms of each non-scalar parameter tensor to be >= this value) param_max_rms: Maximum root-mean-square value of parameter tensor, for purposes of learning the scale on the parameters (we'll constrain the rms of each non-scalar parameter tensor to be <= this value) scalar_max: Maximum absolute value for scalar parameters (applicable if your model has any parameters with numel() == 1). size_update_period: The periodicity, in steps, with which we update the size (scale) of the parameter tensor. This is provided to save a little time in the update. clipping_update_period: if clipping_scale is specified, this is the period """ def __init__( self, params, lr=3e-02, clipping_scale=None, betas=(0.9, 0.98), scalar_lr_scale=0.1, eps=1.0e-08, param_min_rms=1.0e-05, param_max_rms=3.0, scalar_max=10.0, size_update_period=4, clipping_update_period=100, parameters_names=None, show_dominant_parameters=True, ): assert parameters_names is not None, ( "Please prepare parameters_names," "which is a List[List[str]]. Each List[str] is for a group" "and each str is for a parameter" ) defaults = dict( lr=lr, clipping_scale=clipping_scale, betas=betas, scalar_lr_scale=scalar_lr_scale, eps=eps, param_min_rms=param_min_rms, param_max_rms=param_max_rms, scalar_max=scalar_max, size_update_period=size_update_period, clipping_update_period=clipping_update_period, ) super(ScaledAdam, self).__init__(params, defaults) assert len(self.param_groups) == len(parameters_names) self.parameters_names = parameters_names self.show_dominant_parameters = show_dominant_parameters def __setstate__(self, state): super(ScaledAdam, self).__setstate__(state) @torch.no_grad() def step(self, closure=None): """Performs a single optimization step. Arguments: closure (callable, optional): A closure that reevaluates the model and returns the loss. """ loss = None if closure is not None: with torch.enable_grad(): loss = closure() batch = True for group, group_params_names in zip(self.param_groups, self.parameters_names): with self.batched_params(group["params"], group_params_names) as batches: # batches is list of pairs (stacked_param, state). stacked_param is like # a regular parameter, and will have a .grad, but the 1st dim corresponds to # a stacking dim, it is not a real dim. if len(batches[0][1]) == 0: clipping_scale = 1 else: clipping_scale = self._get_clipping_scale(group, batches) for p, state, _ in batches: # Perform optimization step. # grad is not going to be None, we handled that when creating the batches. grad = p.grad if grad.is_sparse: raise RuntimeError( "ScaledAdam optimizer does not support sparse gradients" ) # State initialization if len(state) == 0: self._init_state(group, p, state) self._step_one_batch(group, p, state, clipping_scale) return loss def _init_state(self, group: dict, p: Tensor, state: dict): """ Initializes state dict for parameter 'p'. Assumes that dim 0 of tensor p is actually the batch dimension, corresponding to batched-together parameters of a given shape. Args: group: Dict to look up configuration values. p: The parameter that we are initializing the state for state: Dict from string to whatever state we are initializing """ size_update_period = group["size_update_period"] state["step"] = 0 kwargs = {"device": p.device, "dtype": p.dtype} # 'delta' implements conventional momentum. There are # several different kinds of update going on, so rather than # compute "exp_avg" like in Adam, we store and decay a # parameter-change "delta", which combines all forms of # update. this is equivalent to how it's done in Adam, # except for the first few steps. state["delta"] = torch.zeros_like(p, memory_format=torch.preserve_format) batch_size = p.shape[0] numel = p.numel() // batch_size numel = p.numel() if numel > 1: # "param_rms" just periodically records the scalar root-mean-square value of # the parameter tensor. # it has a shape like (batch_size, 1, 1, 1, 1) param_rms = (p**2).mean(dim=list(range(1, p.ndim)), keepdim=True).sqrt() state["param_rms"] = param_rms state["scale_exp_avg_sq"] = torch.zeros_like(param_rms) state["scale_grads"] = torch.zeros( size_update_period, *param_rms.shape, **kwargs ) # exp_avg_sq is the weighted sum of scaled gradients. as in Adam. state["exp_avg_sq"] = torch.zeros_like(p, memory_format=torch.preserve_format) def _get_clipping_scale( self, group: dict, tuples: List[Tuple[Tensor, dict, List[str]]] ) -> float: """ Returns a scalar factor <= 1.0 that dictates gradient clipping, i.e. we will scale the gradients by this amount before applying the rest of the update. Args: group: the parameter group, an item in self.param_groups tuples: a list of tuples of (param, state, param_names) where param is a batched set of parameters, with a .grad (1st dim is batch dim) and state is the state-dict where optimization parameters are kept. param_names is a List[str] while each str is name for a parameter in batched set of parameters "param". """ assert len(tuples) >= 1 clipping_scale = group["clipping_scale"] (first_p, first_state, _) = tuples[0] step = first_state["step"] if clipping_scale is None or step == 0: # no clipping. return early on step == 0 because the other # parameters' state won't have been initialized yet. return 1.0 clipping_update_period = group["clipping_update_period"] tot_sumsq = torch.tensor(0.0, device=first_p.device) for p, state, param_names in tuples: grad = p.grad if grad.is_sparse: raise RuntimeError( "ScaledAdam optimizer does not support sparse gradients" ) if p.numel() == p.shape[0]: # a batch of scalars tot_sumsq += (grad**2).sum() # sum() to change shape [1] to [] else: tot_sumsq += ((grad * state["param_rms"]) ** 2).sum() tot_norm = tot_sumsq.sqrt() if "model_norms" not in first_state: first_state["model_norms"] = torch.zeros( clipping_update_period, device=p.device ) first_state["model_norms"][step % clipping_update_period] = tot_norm if step % clipping_update_period == 0: # Print some stats. # We don't reach here if step == 0 because we would have returned # above. sorted_norms = first_state["model_norms"].sort()[0].to("cpu") quartiles = [] for n in range(0, 5): index = min( clipping_update_period - 1, (clipping_update_period // 4) * n, ) quartiles.append(sorted_norms[index].item()) median = quartiles[2] threshold = clipping_scale * median first_state["model_norm_threshold"] = threshold percent_clipped = ( first_state["num_clipped"] * 100.0 / clipping_update_period if "num_clipped" in first_state else 0.0 ) first_state["num_clipped"] = 0 quartiles = " ".join(["%.3e" % x for x in quartiles]) logging.info( f"Clipping_scale={clipping_scale}, grad-norm quartiles {quartiles}, " f"threshold={threshold:.3e}, percent-clipped={percent_clipped:.1f}" ) if step < clipping_update_period: return 1.0 # We have not yet estimated a norm to clip to. else: try: model_norm_threshold = first_state["model_norm_threshold"] except KeyError: logging.info( "Warning: model_norm_threshold not in state: possibly " "you changed config when restarting, adding clipping_scale option?" ) return 1.0 ans = min(1.0, (model_norm_threshold / (tot_norm + 1.0e-20)).item()) if ans < 1.0: first_state["num_clipped"] += 1 if ans < 0.1: logging.warn( f"Scaling gradients by {ans}, model_norm_threshold={model_norm_threshold}" ) if self.show_dominant_parameters: assert p.shape[0] == len(param_names) self._show_gradient_dominating_parameter(tuples, tot_sumsq) return ans def _show_gradient_dominating_parameter( self, tuples: List[Tuple[Tensor, dict, List[str]]], tot_sumsq: Tensor ): """ Show information of parameter wihch dominanting tot_sumsq. Args: tuples: a list of tuples of (param, state, param_names) where param is a batched set of parameters, with a .grad (1st dim is batch dim) and state is the state-dict where optimization parameters are kept. param_names is a List[str] while each str is name for a parameter in batched set of parameters "param". tot_sumsq: sumsq of all parameters. Though it's could be calculated from tuples, we still pass it to save some time. """ all_sumsq_orig = {} for p, state, batch_param_names in tuples: # p is a stacked batch parameters. batch_grad = p.grad if p.numel() == p.shape[0]: # a batch of scalars batch_sumsq_orig = batch_grad**2 # Dummpy values used by following `zip` statement. batch_rms_orig = torch.ones(p.shape[0]) else: batch_rms_orig = state["param_rms"] batch_sumsq_orig = ((batch_grad * batch_rms_orig) ** 2).sum( dim=list(range(1, batch_grad.ndim)) ) for name, sumsq_orig, rms, grad in zip( batch_param_names, batch_sumsq_orig, batch_rms_orig, batch_grad ): proportion_orig = sumsq_orig / tot_sumsq all_sumsq_orig[name] = (proportion_orig, sumsq_orig, rms, grad) assert torch.isclose( sum([value[0] for value in all_sumsq_orig.values()]).cpu(), torch.tensor(1.0), ) sorted_by_proportion = { k: v for k, v in sorted( all_sumsq_orig.items(), key=lambda item: item[1][0], reverse=True, ) } dominant_param_name = next(iter(sorted_by_proportion)) ( dominant_proportion, dominant_sumsq, dominant_rms, dominant_grad, ) = sorted_by_proportion[dominant_param_name] logging.info( f"Parameter Dominanting tot_sumsq {dominant_param_name}" f" with proportion {dominant_proportion:.2f}," f" where dominant_sumsq=(grad_sumsq*orig_rms_sq)" f"={dominant_sumsq:.3e}," f" grad_sumsq = {(dominant_grad**2).sum():.3e}," f" orig_rms_sq={(dominant_rms**2).item():.3e}" ) def _step_one_batch( self, group: dict, p: Tensor, state: dict, clipping_scale: float ): """ Do the step for one parameter, which is actually going to be a batch of `real` parameters, with dim 0 as the batch dim. Args: group: dict to look up configuration values p: parameter to update (actually multiple parameters stacked together as a batch) state: state-dict for p, to look up the optimizer state """ lr = group["lr"] size_update_period = group["size_update_period"] beta1 = group["betas"][0] grad = p.grad if clipping_scale != 1.0: grad = grad * clipping_scale step = state["step"] delta = state["delta"] delta.mul_(beta1) batch_size = p.shape[0] numel = p.numel() // batch_size if numel > 1: # Update the size/scale of p, and set param_rms scale_grads = state["scale_grads"] scale_grads[step % size_update_period] = (p * grad).sum( dim=list(range(1, p.ndim)), keepdim=True ) if step % size_update_period == size_update_period - 1: param_rms = state["param_rms"] # shape: (batch_size, 1, 1, ..) param_rms.copy_( (p**2).mean(dim=list(range(1, p.ndim)), keepdim=True).sqrt() ) if step > 0: # self._size_update() learns the overall scale on the # parameter, by shrinking or expanding it. self._size_update(group, scale_grads, p, state) if numel == 1: # For parameters with 1 element we just use regular Adam. # Updates delta. self._step_scalar(group, p, state) else: self._step(group, p, state) state["step"] = step + 1 def _size_update( self, group: dict, scale_grads: Tensor, p: Tensor, state: dict ) -> None: """ Called only where p.numel() > 1, this updates the scale of the parameter. If we imagine: p = underlying_param * scale.exp(), and we are doing gradient descent on underlying param and on scale, this function does the update on `scale`. Args: group: dict to look up configuration values scale_grads: a tensor of shape (size_update_period, batch_size, 1, 1,...) containing grads w.r.t. the scales. p: The parameter to update state: The state-dict of p """ param_rms = state["param_rms"] beta1, beta2 = group["betas"] size_lr = group["lr"] * group["scalar_lr_scale"] param_min_rms = group["param_min_rms"] param_max_rms = group["param_max_rms"] eps = group["eps"] step = state["step"] batch_size = p.shape[0] size_update_period = scale_grads.shape[0] # correct beta2 for the size update period: we will have # faster decay at this level. beta2_corr = beta2**size_update_period scale_exp_avg_sq = state["scale_exp_avg_sq"] # shape: (batch_size, 1, 1, ..) scale_exp_avg_sq.mul_(beta2_corr).add_( (scale_grads**2).mean(dim=0), # mean over dim `size_update_period` alpha=1 - beta2_corr, ) # shape is (batch_size, 1, 1, ...) # The 1st time we reach here is when size_step == 1. size_step = (step + 1) // size_update_period bias_correction2 = 1 - beta2_corr**size_step # we don't bother with bias_correction1; this will help prevent divergence # at the start of training. denom = scale_exp_avg_sq.sqrt() + eps scale_step = -size_lr * (bias_correction2**0.5) * scale_grads.sum(dim=0) / denom is_too_small = param_rms < param_min_rms is_too_large = param_rms > param_max_rms # when the param gets too small, just don't shrink it any further. scale_step.masked_fill_(is_too_small, 0.0) # when it gets too large, stop it from getting any larger. scale_step.masked_fill_(is_too_large, -size_lr * size_update_period) delta = state["delta"] # the factor of (1-beta1) relates to momentum. delta.add_(p * scale_step, alpha=(1 - beta1)) def _step(self, group: dict, p: Tensor, state: dict): """ This function does the core update of self.step(), in the case where the members of the batch have more than 1 element. Args: group: A dict which will be used to look up configuration values p: The parameter to be updated grad: The grad of p state: The state-dict corresponding to parameter p This function modifies p. """ grad = p.grad lr = group["lr"] beta1, beta2 = group["betas"] eps = group["eps"] param_min_rms = group["param_min_rms"] step = state["step"] exp_avg_sq = state["exp_avg_sq"] exp_avg_sq.mul_(beta2).addcmul_(grad, grad, value=(1 - beta2)) this_step = state["step"] - (state["zero_step"] if "zero_step" in state else 0) bias_correction2 = 1 - beta2 ** (this_step + 1) if bias_correction2 < 0.99: # note: not in-place. exp_avg_sq = exp_avg_sq * (1.0 / bias_correction2) denom = exp_avg_sq.sqrt() denom += eps grad = grad / denom alpha = -lr * (1 - beta1) * state["param_rms"].clamp(min=param_min_rms) delta = state["delta"] delta.add_(grad * alpha) p.add_(delta) def _step_scalar(self, group: dict, p: Tensor, state: dict): """ A simplified form of the core update for scalar tensors, where we cannot get a good estimate of the parameter rms. """ beta1, beta2 = group["betas"] scalar_max = group["scalar_max"] eps = group["eps"] lr = group["lr"] * group["scalar_lr_scale"] grad = p.grad exp_avg_sq = state["exp_avg_sq"] # shape: (batch_size,) exp_avg_sq.mul_(beta2).addcmul_(grad, grad, value=1 - beta2) # bias_correction2 is like in Adam. Don't bother with bias_correction1; # slower update at the start will help stability anyway. bias_correction2 = 1 - beta2 ** (state["step"] + 1) denom = (exp_avg_sq / bias_correction2).sqrt() + eps delta = state["delta"] delta.add_(grad / denom, alpha=-lr * (1 - beta1)) p.clamp_(min=-scalar_max, max=scalar_max) p.add_(delta)