# Some code borrowed from the awesome work: https://github.com/zhuzilin/ring-flash-attention # Copyright (c) ModelScope Contributors. All rights reserved. import math import torch import torch.distributed as dist from torch.nn import CrossEntropyLoss from torch.utils.data import Sampler from typing import Any, Iterator, Optional, Tuple from swift.dataloader import DataLoaderDispatcher from .ulysses import sequence_parallel class GatherTensor(torch.autograd.Function): """Gather tensor from sequence group (autograd supported)""" @staticmethod def forward(ctx, tensor, dim=0, position_ids=None): ctx.dim = dim if position_ids is not None: position_ids = sequence_parallel.pad(position_ids, padding_value=-1, position_ids=position_ids) ctx.position_ids = position_ids return sequence_parallel.gather(tensor, dim=dim, position_ids=position_ids) @staticmethod def backward(ctx, grad_output): grad_input = sequence_parallel.split(grad_output, dim=ctx.dim, position_ids=ctx.position_ids) return grad_input, None, None class GatherLoss(torch.autograd.Function): """Gather loss from sequence group""" @staticmethod def forward(ctx, loss, labels, gather_idx=None, position_ids=None): """ Args: loss: loss tensor after splitting labels: labels tensor after splitting gather_idx: gather the tensors on this dim """ # change from label.shape to loss, because label may be None ctx.scatter_shape = loss.shape[gather_idx or 0] ctx.gather_idx = gather_idx or 0 if position_ids is not None: position_ids = sequence_parallel.pad(position_ids, padding_value=-1, position_ids=position_ids) ctx.position_ids = position_ids output = sequence_parallel.gather(loss, dim=ctx.gather_idx, position_ids=position_ids) if labels is not None: labels_output = sequence_parallel.gather(labels, dim=ctx.gather_idx, position_ids=position_ids) else: labels_output = None return output, labels_output @staticmethod def backward(ctx, *grad_output): _grad = grad_output[0] * sequence_parallel.world_size if sequence_parallel.rp_world_size > 1: _grad = sequence_parallel.split(_grad, dim=ctx.gather_idx, position_ids=ctx.position_ids).contiguous() else: _grad = _grad.split( ctx.scatter_shape, dim=ctx.gather_idx)[dist.get_rank(sequence_parallel.sp_group)].contiguous() return _grad, None, None, None class ChunkedCrossEntropyLoss(torch.autograd.Function): @staticmethod def forward(ctx, logits, labels, chunk_size): ctx.save_for_backward(logits, labels) ctx.chunk_size = chunk_size losses = [] for i in range(math.ceil(logits.shape[0] / chunk_size)): l_start = i * chunk_size l_end = min((i + 1) * chunk_size, logits.shape[0]) logits_chunk = logits[l_start:l_end] labels_chunk = labels[l_start:l_end] loss_fct = CrossEntropyLoss(reduction='none') loss_chunk = loss_fct(logits_chunk, labels_chunk) losses.append(loss_chunk) del logits_chunk del labels_chunk all_losses = torch.cat(losses) return all_losses @staticmethod def backward(ctx: Any, *grad_outputs: Any): logits, labels = ctx.saved_tensors chunk_size = ctx.chunk_size for i in range(math.ceil(logits.shape[0] / chunk_size)): l_start = i * chunk_size l_end = min((i + 1) * chunk_size, logits.shape[0]) logits_chunk = logits[l_start:l_end].detach().requires_grad_(True) labels_chunk = labels[l_start:l_end] loss_fct = CrossEntropyLoss(reduction='none') with torch.enable_grad(): loss_chunk = loss_fct(logits_chunk, labels_chunk) grad_output_chunk = grad_outputs[0][l_start:l_end] _loss_chunk = (loss_chunk * grad_output_chunk).sum() grad_chunk = torch.autograd.grad(_loss_chunk, logits_chunk, retain_graph=False)[0] logits[l_start:l_end] = grad_chunk return logits, None, None class SequenceParallelSampler(Sampler): """Sampler for sequence parallel training""" def __init__(self, sp_instance, dataset, shuffle: bool = True, seed=None, round_up: bool = True) -> None: self.sp_instance = sp_instance rank = dist.get_rank(sp_instance.device_mesh['data'].get_group()) world_size = sp_instance.device_mesh['data'].size() self.rank = rank self.world_size = world_size self.dataset = dataset self.shuffle = shuffle assert seed is not None self.seed = seed self.epoch = 0 self.round_up = round_up if self.round_up: self.num_samples = math.ceil(len(self.dataset) / world_size) self.total_size = self.num_samples * self.world_size else: self.num_samples = math.ceil((len(self.dataset) - rank) / world_size) self.total_size = len(self.dataset) def __iter__(self) -> Iterator[int]: if self.shuffle: g = torch.Generator() g.manual_seed(self.seed + self.epoch) indices = torch.randperm(len(self.dataset), generator=g).tolist() else: indices = torch.arange(len(self.dataset)).tolist() if self.round_up: indices = (indices * int(self.total_size / len(indices) + 1))[:self.total_size] indices = indices[self.rank:self.total_size:self.world_size] return iter(indices) def __len__(self) -> int: return self.num_samples def set_epoch(self, epoch: int) -> None: self.epoch = epoch class SequenceParallelDispatcher(DataLoaderDispatcher): """Dispatcher for sequence parallel training""" def __init__(self, dataloader, sp_instance, device=None, skip_batches: int = 0): super().__init__(dataloader) self.sp_instance = sp_instance self.device = device self.skip_batches = skip_batches @property def rank(self): return self.sp_instance.dp_rank if dist.is_initialized() else 0 @property def world_size(self): return self.sp_instance.dp_world_size if dist.is_initialized() else 1 @property def group(self): return self.sp_instance.dp_group if dist.is_initialized() else 1 class RingComm: def __init__(self, process_group: dist.ProcessGroup): self._process_group = process_group self._ops = [] self.rank = dist.get_rank(self._process_group) self.world_size = dist.get_world_size(self._process_group) self._reqs = None self.send_rank = (self.rank + 1) % self.world_size self.recv_rank = (self.rank - 1) % self.world_size if process_group is not None: self.send_rank = dist.get_global_rank(self._process_group, self.send_rank) self.recv_rank = dist.get_global_rank(self._process_group, self.recv_rank) def send_recv(self, to_send: torch.Tensor, recv_tensor: Optional[torch.Tensor] = None) -> torch.Tensor: if recv_tensor is None: res = torch.empty_like(to_send) else: res = recv_tensor send_op = dist.P2POp(dist.isend, to_send, self.send_rank, group=self._process_group) recv_op = dist.P2POp(dist.irecv, res, self.recv_rank, group=self._process_group) self._ops.append(send_op) self._ops.append(recv_op) return res def commit(self): if self._reqs is not None: raise RuntimeError('commit called twice') self._reqs = dist.batch_isend_irecv(self._ops) def wait(self): if self._reqs is None: raise RuntimeError('wait called before commit') for req in self._reqs: req.wait() self._reqs = None self._ops = [] def send_recv_kv( self, k: torch.Tensor, v: torch.Tensor, k_buffer: Optional[torch.Tensor] = None, v_buffer: Optional[torch.Tensor] = None, ) -> Tuple[torch.Tensor, torch.Tensor]: next_k, next_v = self.send_recv(k, k_buffer), self.send_recv(v, v_buffer) self.commit() return next_k, next_v