mirror of https://github.com/hpcaitech/ColossalAI
571 lines
21 KiB
Python
571 lines
21 KiB
Python
import torch
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import torch.distributed as dist
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import torch.nn.functional as F
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try:
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import fused_mix_prec_layer_norm_cuda
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except:
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fused_mix_prec_layer_norm_cuda = None
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class FusedLayerNormAffineFunction1D(torch.autograd.Function):
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r"""Layernorm
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Args:
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input: input matrix.
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weight: weight matrix.
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bias: bias matrix.
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normalized_shape: input shape from an expected input of size.
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:math:`[* \times \text{normalized_shape}[0] \times \text{normalized_shape}[1] \times \ldots \times \text{normalized_shape}[-1]]`
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If a single integer is used, it is treated as a singleton list, and this module will
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normalize over the last dimension which is expected to be of that specific size.
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eps: a value added to the denominator for numerical stability
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"""
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@staticmethod
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def forward(ctx, input, weight, bias, normalized_shape, eps):
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ctx.normalized_shape = normalized_shape
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ctx.eps = eps
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input_ = input.contiguous()
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weight_ = weight.contiguous()
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bias_ = bias.contiguous()
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output, mean, invvar = fused_mix_prec_layer_norm_cuda.forward_affine(
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input_, ctx.normalized_shape, weight_, bias_, ctx.eps
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)
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ctx.save_for_backward(input_, weight_, bias_, mean, invvar)
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return output
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@staticmethod
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def backward(ctx, grad_output):
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input_, weight_, bias_, mean, invvar = ctx.saved_tensors
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grad_input = grad_weight = grad_bias = None
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grad_input, grad_weight, grad_bias = fused_mix_prec_layer_norm_cuda.backward_affine(
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grad_output.contiguous(), mean, invvar, input_, ctx.normalized_shape, weight_, bias_, ctx.eps
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)
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return grad_input, grad_weight, grad_bias, None, None
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class MatmulWithAsyncCommunication(torch.autograd.Function):
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"""
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Linear layer execution with asynchronous communication in backprop.
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"""
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@staticmethod
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def forward(ctx, input_, weight, bias, process_group, async_grad_allreduce):
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ctx.save_for_backward(input_, weight)
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ctx.use_bias = bias is not None
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ctx.process_group = process_group
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ctx.async_grad_allreduce = async_grad_allreduce
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output = torch.matmul(input_, weight)
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if bias is not None:
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output = output + bias
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return output
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@staticmethod
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def backward(ctx, grad_output):
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input, weight = ctx.saved_tensors
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use_bias = ctx.use_bias
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total_input = input
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grad_input = grad_output.matmul(weight.T)
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grad_output = grad_output.contiguous()
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# Convert the tensor shapes to 2D for execution compatibility
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if len(grad_output.shape) > 2:
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grad_output = grad_output.view(-1, grad_output.shape[-1])
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total_input = total_input.view(-1, total_input.shape[-1])
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if ctx.async_grad_allreduce:
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# Asynchronous all-reduce
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handle = dist.all_reduce(grad_input, group=ctx.process_group, async_op=True)
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# Delay the start of weight gradient computation shortly (3us) to have
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# all-reduce scheduled first and have GPU resources allocated
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_ = torch.empty(1, device=grad_output.device) + 1
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grad_weight = total_input.t().matmul(grad_output)
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grad_bias = grad_output.sum(dim=0) if use_bias else None
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if ctx.async_grad_allreduce:
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handle.wait()
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return grad_input, grad_weight, grad_bias, None, None, None
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class LinearWithAsyncCommunication(torch.autograd.Function):
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"""
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Linear layer execution with asynchronous communication in backprop.
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"""
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@staticmethod
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def forward(ctx, input_, weight, bias, process_group, async_grad_allreduce):
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ctx.save_for_backward(input_, weight)
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ctx.use_bias = bias is not None
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ctx.process_group = process_group
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ctx.async_grad_allreduce = async_grad_allreduce
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if bias is not None:
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output = F.linear(input_, weight, bias)
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else:
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output = F.linear(input_, weight)
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return output
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@staticmethod
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def backward(ctx, grad_output):
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input, weight = ctx.saved_tensors
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use_bias = ctx.use_bias
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total_input = input
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grad_input = grad_output.matmul(weight)
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grad_output = grad_output.contiguous()
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# Convert the tensor shapes to 2D for execution compatibility
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if len(grad_output.shape) > 2:
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grad_output = grad_output.view(-1, grad_output.shape[-1])
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total_input = total_input.view(-1, total_input.shape[-1])
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if ctx.async_grad_allreduce:
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# Asynchronous all-reduce
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handle = dist.all_reduce(grad_input, group=ctx.process_group, async_op=True)
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# Delay the start of weight gradient computation shortly (3us) to have
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# all-reduce scheduled first and have GPU resources allocated
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_ = torch.empty(1, device=grad_output.device) + 1
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grad_weight = grad_output.t().matmul(total_input)
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grad_bias = grad_output.sum(dim=0) if use_bias else None
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if ctx.async_grad_allreduce:
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handle.wait()
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return grad_input, grad_weight, grad_bias, None, None, None
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class _LinearWithGatherForwardReduceScatterBackward(torch.autograd.Function):
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"""Gather input from sequence parallel in forward and reduce-scatter gradient in backward
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Args:
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input_ (`torch.Tensor`): The input tensor from sequence parallel region.
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process_group (`torch.distributed.ProcessGroup`): The process group used for collective communication.
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overlap (`bool`): Whther to overlap the all_gather op and gradient calculate in backward.
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"""
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@staticmethod
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def forward(ctx, input_, weight, bias, process_group, async_grad_reduce_scatter, dim, overlap=True):
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ctx.save_for_backward(input_, weight)
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ctx.use_bias = bias is not None
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ctx.process_group = process_group
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ctx.async_grad_reduce_scatter = async_grad_reduce_scatter
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ctx.dim = dim
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ctx.overlap = overlap
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input_parallel = _gather(input_, dim, process_group)
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if bias is not None:
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output = F.linear(input_parallel, weight, bias)
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else:
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output = F.linear(input_parallel, weight)
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return output
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@staticmethod
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def backward(ctx, grad_output):
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input_, weight = ctx.saved_tensors
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use_bias = ctx.use_bias
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dim = ctx.dim
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process_group = ctx.process_group
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overlap = ctx.overlap
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if not overlap:
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input_parallel = _gather(input_, dim, process_group)
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total_input = input_parallel
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grad_input = grad_output.matmul(weight)
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grad_output = grad_output.contiguous()
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# Convert the tensor shapes to 2D for execution compatibility
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if len(grad_output.shape) > 2:
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grad_output = grad_output.view(-1, grad_output.shape[-1])
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total_input = total_input.view(-1, total_input.shape[-1])
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if ctx.async_grad_reduce_scatter:
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# Asynchronous reduce-scatter
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input_list = [
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item.contiguous() for item in torch.chunk(grad_input, dist.get_world_size(process_group), dim=dim)
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]
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output = torch.empty(
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input_.shape, dtype=input_parallel.dtype, device=input_parallel.device
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).contiguous()
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handle = dist.reduce_scatter(output, input_list, group=process_group, async_op=True)
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# Delay the start of weight gradient computation shortly (3us) to have
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# reduce-scatter scheduled first and have GPU resources allocated
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_ = torch.empty(1, device=grad_output.device) + 1
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grad_weight = grad_output.t().matmul(total_input)
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grad_bias = grad_output.sum(dim=0) if use_bias else None
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if ctx.async_grad_reduce_scatter:
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handle.wait()
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else:
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input_ = input_.contiguous()
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world_size = dist.get_world_size(process_group)
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tensor_list = [torch.empty_like(input_) for _ in range(world_size)]
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# do all gather in is async way
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gather_handle = dist.all_gather(tensor_list, input_, group=process_group, async_op=True)
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# calculate gradient and prepare data asynchronously with all-gather
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# calculate
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grad_input = grad_output.matmul(weight)
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grad_output = grad_output.contiguous()
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# Convert the tensor shapes to 2D for execution compatibility
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if len(grad_output.shape) > 2:
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grad_output = grad_output.view(-1, grad_output.shape[-1])
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grad_bias = grad_output.sum(dim=0) if use_bias else None
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# prepare data
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input_list = [
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item.contiguous() for item in torch.chunk(grad_input, dist.get_world_size(process_group), dim=dim)
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]
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output = torch.empty(input_.shape, dtype=input_.dtype, device=input_.device).contiguous()
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# wait until all-gather finished
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gather_handle.wait()
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# do reduce-scatter in async way
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reducescatter_handle = dist.reduce_scatter(output, input_list, group=process_group, async_op=True)
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input_parallel = torch.cat(tensor_list, dim=dim).contiguous()
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# calculate gradient
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if len(input_parallel.shape) > 2:
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input_parallel = input_parallel.view(-1, input_parallel.shape[-1])
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grad_weight = grad_output.t().matmul(input_parallel)
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# wait until reduce-scatter finished
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reducescatter_handle.wait()
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return output, grad_weight, grad_bias, None, None, None, None
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class _LinearWithReduceScatterForwardGatherBackward(torch.autograd.Function):
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"""Gather input from sequence parallel in forward and reduce-scatter gradient in backward
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Args:
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input_ (`torch.Tensor`): The input tensor from sequence parallel region.
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process_group (`torch.distributed.ProcessGroup`): The process group used for collective communication.
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"""
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@staticmethod
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def forward(ctx, input_, process_group, dim):
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ctx.dim = dim
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ctx.process_group = process_group
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# do reduce-scatter
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new_shape = list(input_.shape)
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assert (
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new_shape[dim] % dist.get_world_size(process_group) == 0
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), f"The dimension to split ({new_shape[dim]}) is not a multiple of tensor parallel size ({dist.get_world_size(process_group)}). "
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new_shape[dim] = new_shape[dim] // dist.get_world_size(process_group)
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input_list = [item.contiguous() for item in torch.chunk(input_, dist.get_world_size(process_group), dim=dim)]
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output = torch.empty(new_shape, dtype=input_.dtype, device=input_.device)
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dist.reduce_scatter(output, input_list, group=process_group)
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return output
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@staticmethod
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def backward(ctx, grad_output):
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dim = ctx.dim
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process_group = ctx.process_group
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return _gather(grad_output, dim, process_group), None, None
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class _MatmulWithGatherForwardReduceScatterBackward(torch.autograd.Function):
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"""
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This class is designed for matmul operation with gather forward and reduce-scatter backward.
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Args:
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input_ (`torch.Tensor`): input matrix.
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dim (int): the dimension to perform split and gather
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process_group (`torch.distributed.ProcessGroup`): the process group used for collective communication
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"""
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@staticmethod
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def forward(ctx, input_, weight, bias, process_group, async_grad_reduce_scatter, dim, overlap):
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ctx.save_for_backward(input_, weight)
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ctx.use_bias = bias is not None
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ctx.process_group = process_group
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ctx.async_grad_reduce_scatter = async_grad_reduce_scatter
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ctx.dim = dim
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ctx.overlap = overlap
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input_parallel = _gather(input_, dim, process_group)
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output = torch.matmul(input_parallel, weight)
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if bias is not None:
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output = output + bias
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return output
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@staticmethod
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def backward(ctx, grad_output):
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input_, weight = ctx.saved_tensors
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use_bias = ctx.use_bias
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dim = ctx.dim
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process_group = ctx.process_group
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overlap = ctx.overlap
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if not overlap:
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input_parallel = _gather(input_, dim, process_group)
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total_input = input_parallel
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grad_input = grad_output.matmul(weight.T)
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grad_output = grad_output.contiguous()
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# Convert the tensor shapes to 2D for execution compatibility
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if len(grad_output.shape) > 2:
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grad_output = grad_output.view(-1, grad_output.shape[-1])
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total_input = total_input.view(-1, total_input.shape[-1])
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if ctx.async_grad_reduce_scatter:
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# Asynchronous reduce-scatter
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input_list = [
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item.contiguous() for item in torch.chunk(grad_input, dist.get_world_size(process_group), dim=dim)
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]
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output = torch.empty(
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input_.shape, dtype=input_parallel.dtype, device=input_parallel.device
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).contiguous()
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handle = dist.reduce_scatter(output, input_list, group=process_group, async_op=True)
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# Delay the start of weight gradient computation shortly (3us) to have
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# reduce-scatter scheduled first and have GPU resources allocated
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_ = torch.empty(1, device=grad_output.device) + 1
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grad_weight = total_input.t().matmul(grad_output)
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grad_bias = grad_output.sum(dim=0) if use_bias else None
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if ctx.async_grad_reduce_scatter:
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handle.wait()
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else:
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world_size = dist.get_world_size(process_group)
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tensor_list = [torch.empty_like(input_) for _ in range(world_size)]
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# do all gather in is async way
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gather_handle = dist.all_gather(tensor_list, input_, group=process_group, async_op=True)
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# calculate gradient and prepare data asynchronously with all-gather
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# calculate
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grad_input = grad_output.matmul(weight.T)
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grad_output = grad_output.contiguous()
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# Convert the tensor shapes to 2D for execution compatibility
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if len(grad_output.shape) > 2:
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grad_output = grad_output.view(-1, grad_output.shape[-1])
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grad_bias = grad_output.sum(dim=0) if use_bias else None
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# prepare data
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input_list = [
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item.contiguous() for item in torch.chunk(grad_input, dist.get_world_size(process_group), dim=dim)
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]
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output = torch.empty(input_.shape, dtype=input_.dtype, device=input_.device).contiguous()
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# wait until all-gather finished
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gather_handle.wait()
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# do reduce-scatter in async way
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reducescatter_handle = dist.reduce_scatter(output, input_list, group=process_group, async_op=True)
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input_parallel = torch.cat(tensor_list, dim=dim).contiguous()
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# calculate gradient
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if len(input_parallel.shape) > 2:
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input_parallel = input_parallel.view(-1, input_parallel.shape[-1])
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grad_weight = input_parallel.t().matmul(grad_output)
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# wait until reduce-scatter finished
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reducescatter_handle.wait()
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return output, grad_weight, grad_bias, None, None, None, None
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class _SplitForwardGatherBackward(torch.autograd.Function):
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"""
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Split the input and keep only the corresponding chuck to the rank.
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Args:
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input_ (`torch.Tensor`): input matrix.
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dim (int): the dimension to perform split and gather
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process_group (`torch.distributed.ProcessGroup`): the process group used for collective communication
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"""
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@staticmethod
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def forward(ctx, input_, dim, process_group):
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ctx.process_group = process_group
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ctx.dim = dim
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return _split(input_, dim, process_group)
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@staticmethod
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def backward(ctx, grad_output):
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return _gather(grad_output, ctx.dim, ctx.process_group), None, None
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class _ReduceForward(torch.autograd.Function):
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"""
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All-reduce the input from the model parallel region.
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Args:
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input_: input matrix.
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parallel_mode: parallel mode.
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"""
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@staticmethod
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def forward(ctx, input_, process_group):
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return _reduce(input_, process_group)
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@staticmethod
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def backward(ctx, grad_output):
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return grad_output, None
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class _ReduceBackward(torch.autograd.Function):
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"""
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All-reduce the input from the model parallel region.
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Args:
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input_: input matrix.
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parallel_mode: parallel mode.
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"""
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@staticmethod
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def forward(ctx, input_, process_group):
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ctx.process_group = process_group
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return input_
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@staticmethod
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def backward(ctx, grad_output):
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return _reduce(grad_output, ctx.process_group), None
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class _GatherForwardSplitBackward(torch.autograd.Function):
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"""Gather the input from model parallel region and concatenate.
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Args:
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input_: input matrix.
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parallel_mode: parallel mode.
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dim: dimension
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"""
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@staticmethod
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def forward(ctx, input_, dim, process_group):
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ctx.process_group = process_group
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ctx.dim = dim
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return _gather(input_, dim, process_group)
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@staticmethod
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def backward(ctx, grad_output):
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return _split(grad_output, ctx.dim, ctx.process_group), None, None
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def _reduce(input_, process_group):
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# skip if only one rank involved
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if dist.get_world_size(process_group) == 1:
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return input_
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else:
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dist.all_reduce(input_, group=process_group)
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return input_
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def _split(input_, dim=-1, process_group=None):
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# skip if only one rank involved
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world_size = dist.get_world_size(process_group)
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if world_size == 1:
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return input_
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# Split along last dimension.
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dim_size = input_.size(dim)
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assert dim_size % world_size == 0, (
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f"The dimension to split ({dim_size}) is not a multiple of world size ({world_size}), "
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f"cannot split tensor evenly"
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)
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tensor_list = torch.split(input_, dim_size // world_size, dim=dim)
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rank = dist.get_rank(process_group)
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output = tensor_list[rank].contiguous()
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return output
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def _gather(input_, dim=-1, process_group=None):
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# skip if only one rank involved
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world_size = dist.get_world_size(process_group)
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if world_size == 1:
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return input_
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# all gather
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input_ = input_.contiguous()
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tensor_list = [torch.empty_like(input_) for _ in range(world_size)]
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torch.distributed.all_gather(tensor_list, input_, group=process_group)
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|
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# concat
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output = torch.cat(tensor_list, dim=dim).contiguous()
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|
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|
return output
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|
|
|
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|
def _reduce_scatter(input_, dim=1, process_group=None):
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|
"""Do reduce-scatter operation.
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|
|
|
Args:
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|
input_ (`torch.Tensor`): The input tensor from sequence parallel region.
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dim (int): The dimension to perform reduce-scatter.
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|
process_group (`torch.distributed.ProcessGroup`): The process group used for collective communication.
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|
"""
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|
world_size = dist.get_world_size(process_group)
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if world_size == 1:
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return input_
|
|
|
|
# reduce-scatter
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|
new_shape = list(input_.shape)
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|
assert (
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|
new_shape[dim] % dist.get_world_size(process_group) == 0
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|
), f"The dimension to split ({new_shape[dim]}) is not a multiple of tensor parallel size ({dist.get_world_size(process_group)}). "
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|
new_shape[dim] = new_shape[dim] // world_size
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|
output = torch.empty(new_shape, dtype=input_.dtype, device=input_.device)
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|
dist.reduce_scatter(output, input_, group=process_group)
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|
|
|
return output
|
|
|
|
|
|
def matmul_with_async_comm(input_, weight, bias, process_group, async_grad_allreduce):
|
|
return MatmulWithAsyncCommunication.apply(input_, weight, bias, process_group, async_grad_allreduce)
|
|
|
|
|
|
def linear_with_async_comm(input_, weight, bias, process_group, async_grad_allreduce):
|
|
return LinearWithAsyncCommunication.apply(input_, weight, bias, process_group, async_grad_allreduce)
|
|
|
|
|
|
def linear_gather_forward_reducescatter_backward(
|
|
input_, weight, bias, process_group, async_grad_reduce_scatter, dim, overlap
|
|
):
|
|
return _LinearWithGatherForwardReduceScatterBackward.apply(
|
|
input_, weight, bias, process_group, async_grad_reduce_scatter, dim, overlap
|
|
)
|
|
|
|
|
|
def linear_reducescatter_forward_gather_backward(input_, process_group, dim):
|
|
return _LinearWithReduceScatterForwardGatherBackward.apply(input_, process_group, dim)
|
|
|
|
|
|
def matmul_gather_forward_reducescatter_backward(
|
|
input_, weight, bias, process_group, async_grad_reduce_scatter, dim, overlap
|
|
):
|
|
return _MatmulWithGatherForwardReduceScatterBackward.apply(
|
|
input_, weight, bias, process_group, async_grad_reduce_scatter, dim, overlap
|
|
)
|
|
|
|
|
|
def gather_forward_split_backward(input_, dim, process_group):
|
|
return _GatherForwardSplitBackward.apply(input_, dim, process_group)
|
|
|
|
|
|
def split_forward_gather_backward(input_, dim, process_group):
|
|
return _SplitForwardGatherBackward.apply(input_, dim, process_group)
|
|
|
|
|
|
def reduce_forward(input_, process_group):
|
|
return _ReduceForward.apply(input_, process_group)
|
|
|
|
|
|
def reduce_backward(input_, process_group):
|
|
return _ReduceBackward.apply(input_, process_group)
|