#!/usr/bin/env python # -*- encoding: utf-8 -*- import torch from torch import distributed as dist from colossalai.communication import ring_forward from colossalai.context.parallel_mode import ParallelMode from colossalai.core import global_context as gpc from colossalai.nn.layer.parallel_sequence._utils import _calc_incoming_device_range, _calc_current_device_range from colossalai.utils import get_current_device class RingQK(torch.autograd.Function): """ Calculate QK in a ring-exchange style """ @staticmethod def forward(ctx, sub_q, sub_k, batch_size, num_attention_heads, sub_seq_length): # save tensor for backward ctx.save_for_backward(sub_q, sub_k) ctx.sub_seq_length = sub_seq_length # create local segment of attention score attention_score = torch.empty( batch_size * num_attention_heads, sub_seq_length, sub_seq_length * gpc.get_world_size(ParallelMode.SEQUENCE), dtype=sub_q.dtype, device=get_current_device() ) # compute local QK^T part_a = torch.matmul(sub_q, sub_k.transpose(2, 1)) local_rank = gpc.get_local_rank(ParallelMode.SEQUENCE) local_world_size = gpc.get_world_size(ParallelMode.SEQUENCE) start_idx = local_rank * sub_seq_length end_idx = (local_rank + 1) * sub_seq_length attention_score[:, :, start_idx: end_idx] = part_a # compute QK^T in ring-all-reduce style for i in range(local_world_size - 1): sub_k = ring_forward(sub_k, ParallelMode.SEQUENCE) start_idx, end_idx = _calc_incoming_device_range(i, local_rank, local_world_size, sub_seq_length) part_a = torch.matmul(sub_q, sub_k.transpose(2, 1)) attention_score[:, :, start_idx:end_idx] = part_a return attention_score @staticmethod def backward(ctx, grad_output): sub_q, sub_k, = ctx.saved_tensors local_rank = gpc.get_local_rank(ParallelMode.SEQUENCE) local_world_size = gpc.get_world_size(ParallelMode.SEQUENCE) # calculate gradient of sub_k grad_k = torch.matmul( grad_output.transpose(2, 1), sub_q ) dist.all_reduce(grad_k, group=gpc.get_group(ParallelMode.SEQUENCE)) grad_k = grad_k[:, local_rank * ctx.sub_seq_length: (local_rank + 1) * ctx.sub_seq_length] grad_k /= local_world_size # calculate gradient for sub_q grad_q = torch.zeros_like(sub_q, dtype=sub_q.dtype, device=get_current_device(), ) # compute with local sub_k start_idx, end_idx = _calc_current_device_range(local_rank, ctx.sub_seq_length) grad_q += torch.matmul(grad_output[:, :, start_idx:end_idx], sub_k) # compute QK^T in ring-all-reduce style for i in range(local_world_size - 1): sub_k = ring_forward(sub_k, ParallelMode.SEQUENCE) start_idx, end_idx = _calc_incoming_device_range(i, local_rank, local_world_size, ctx.sub_seq_length) grad_q += torch.matmul(grad_output[:, :, start_idx: end_idx], sub_k) grad_q /= local_world_size return grad_q, grad_k, None, None, None class RingAV(torch.autograd.Function): """ Calculate AV in a ring-exchange style """ @staticmethod def forward(ctx, attention_score, sub_v, batch_size, num_attention_heads, attention_head_size, sub_seq_length): local_rank = gpc.get_local_rank(ParallelMode.SEQUENCE) local_world_size = gpc.get_world_size(ParallelMode.SEQUENCE) local_start_idx, local_end_idx = _calc_current_device_range(local_rank, sub_seq_length) sub_attention_result = torch.zeros( batch_size * num_attention_heads, sub_seq_length, attention_head_size, device=get_current_device(), dtype=attention_score.dtype) # save tensors for backward ctx.save_for_backward(attention_score, sub_v) ctx.sub_seq_length = sub_seq_length # compute local AV part_av = torch.matmul(attention_score[:, :, local_start_idx:local_end_idx], sub_v) sub_attention_result += part_av # compute AV in ring - all - reduce style for i in range(local_world_size - 1): sub_v = ring_forward(sub_v, ParallelMode.SEQUENCE) start_idx, end_idx = _calc_incoming_device_range(i, local_rank, local_world_size, sub_seq_length) # compute QK^T part_av = torch.matmul(attention_score[:, :, start_idx:end_idx], sub_v) sub_attention_result += part_av return sub_attention_result @staticmethod def backward(ctx, grad_output): local_rank = gpc.get_local_rank(ParallelMode.SEQUENCE) local_world_size = gpc.get_world_size(ParallelMode.SEQUENCE) local_start_idx, local_end_idx = _calc_current_device_range(local_rank, ctx.sub_seq_length) attention_scores, sub_v = ctx.saved_tensors # calculate gradient of v grad_v = torch.matmul( attention_scores.transpose(2, 1), grad_output ) dist.all_reduce(grad_v, group=gpc.get_group(ParallelMode.SEQUENCE)) grad_v = grad_v[:, local_start_idx:local_end_idx] grad_v /= local_world_size # calculate gradient for attention score grad_attention_score = torch.zeros_like(attention_scores, dtype=grad_output.dtype, device=get_current_device()) # compute with local sub_k grad_attention_score[:, :, local_start_idx:local_end_idx] += torch.matmul( grad_output, sub_v.transpose(2, 1)) # compute QK^T in ring-all-reduce style for i in range(local_world_size - 1): sub_v = ring_forward(sub_v, ParallelMode.SEQUENCE) start_idx, end_idx = _calc_incoming_device_range(i, local_rank, local_world_size, ctx.sub_seq_length) # compute grad_q grad_attention_score[:, :, start_idx:end_idx] += torch.matmul( grad_output, sub_v.transpose(2, 1)) return grad_attention_score, grad_v, None, None, None, None