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| import torch.nn as nn |
| import torch |
| import sys |
| from fairseq import utils |
| from fairseq.distributed import utils as distributed_utils |
| from fairseq.modules.layer_norm import LayerNorm |
|
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|
|
| class BaseLayer(nn.Module): |
|
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| def __init__(self, args): |
| super().__init__() |
| self.num_workers = distributed_utils.get_data_parallel_world_size() |
| expert_centroids = torch.empty(self.num_workers, args.decoder_embed_dim) |
| torch.nn.init.orthogonal_(expert_centroids, gain=0.1) |
| self.register_parameter("expert_centroids", torch.nn.Parameter(expert_centroids)) |
| self.expert_network = nn.Sequential(*([BaseSublayer(args) for _ in range(args.base_sublayers)])) |
| self.expert_id = distributed_utils.get_data_parallel_rank() |
| self.shuffle = args.base_shuffle |
| self.cpp = self.load_assignment() |
|
|
| |
| for param in self.expert_network.parameters(): |
| param.expert = True |
|
|
| def forward(self, input_features, *args, **kwargs): |
| features = input_features.reshape(-1, input_features.size(-1)) |
| is_training = input_features.requires_grad |
|
|
| if self.shuffle and is_training: |
| |
| shuffle_sort = torch.randperm(features.size(0), device=features.device) |
| features = All2All.apply(features[shuffle_sort]) |
|
|
| with torch.no_grad(): |
| |
| token_expert_affinities = features.matmul(self.expert_centroids.transpose(0, 1)) |
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| |
| sort_by_expert, input_splits, output_splits = self.balanced_assignment(token_expert_affinities) \ |
| if is_training else self.greedy_assignment(token_expert_affinities) |
| |
| routed_features = All2All.apply(features[sort_by_expert], output_splits, input_splits) |
|
|
| if routed_features.size(0) > 0: |
| |
| alpha = torch.sigmoid(routed_features.mv(self.expert_centroids[self.expert_id])).unsqueeze(1) |
| routed_features = alpha * self.expert_network(routed_features) + (1 - alpha) * routed_features |
| |
| result = All2All.apply(routed_features, input_splits, output_splits)[self.inverse_sort(sort_by_expert)] |
|
|
| if self.shuffle and is_training: |
| |
| result = All2All.apply(result)[self.inverse_sort(shuffle_sort)] |
|
|
| |
| return result.view(input_features.size()), None, None |
|
|
| def inverse_sort(self, order): |
| |
| return torch.empty_like(order).scatter_(0, order, torch.arange(0, order.size(0), device=order.device)) |
|
|
| def balanced_assignment(self, scores): |
| ok = scores.isfinite() |
| if not ok.all(): |
| |
| scores[~ok] = scores[ok].min() |
| return self.cpp.balanced_assignment(scores), None, None |
|
|
| |
| def greedy_assignment(self, scores, k=1): |
| token_to_workers = torch.topk(scores, dim=1, k=k, largest=True).indices.view(-1) |
| token_to_workers, sort_ordering = torch.sort(token_to_workers) |
| worker2token = sort_ordering // k |
|
|
| |
| output_splits = torch.zeros((self.num_workers,), dtype=torch.long, device=scores.device) |
| workers, counts = torch.unique_consecutive(token_to_workers, return_counts=True) |
| output_splits[workers] = counts |
| |
| input_splits = All2All.apply(output_splits) |
| return worker2token, input_splits.tolist(), output_splits.tolist() |
|
|
| def load_assignment(self): |
| try: |
| from fairseq import libbase |
|
|
| return libbase |
|
|
| except ImportError as e: |
| sys.stderr.write( |
| "ERROR: missing libbase. run `python setup.py build_ext --inplace`\n" |
| ) |
| raise e |
|
|
|
|
| class BaseSublayer(nn.Module): |
| def __init__(self, args): |
| super().__init__() |
| self.activation_fn = utils.get_activation_fn( |
| activation=getattr(args, 'activation_fn', 'relu') or "relu" |
| ) |
| self.norm = LayerNorm(args.decoder_embed_dim, export=False) |
| self.ff1 = torch.nn.Linear(args.decoder_embed_dim, args.decoder_ffn_embed_dim) |
| self.ff2 = torch.nn.Linear(args.decoder_ffn_embed_dim, args.decoder_embed_dim) |
| self.ff2.weight.data.zero_() |
|
|
| def forward(self, xs): |
| return xs + self.ff2(self.activation_fn(self.ff1(self.norm(xs)))) |
|
|
|
|
| |
| class All2All(torch.autograd.Function): |
| @staticmethod |
| def forward(ctx, xs, input_splits=None, output_splits=None): |
| ctx.input_splits = input_splits |
| ctx.output_splits = output_splits |
|
|
| ys = torch.empty_like(xs) if output_splits is None else \ |
| xs.new_empty(size=[sum(output_splits)] + list(xs.size()[1:])) |
| torch.distributed.all_to_all_single(ys, xs, output_split_sizes=output_splits, input_split_sizes=input_splits) |
| return ys |
|
|
| @staticmethod |
| def backward(ctx, grad_output): |
| result = torch.empty_like(grad_output) if ctx.input_splits is None else \ |
| grad_output.new_empty(size=[sum(ctx.input_splits)] + list(grad_output.size()[1:])) |
| torch.distributed.all_to_all_single(result, grad_output, |
| output_split_sizes=ctx.input_splits, input_split_sizes=ctx.output_splits) |
| return result, None, None |
|
|