mirror of https://github.com/hpcaitech/ColossalAI
167 lines
10 KiB
Python
167 lines
10 KiB
Python
from typing import Callable, Dict, List, Tuple, Union
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import torch
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from colossalai.auto_parallel.tensor_shard.sharding_strategy import (
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MemoryCost,
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OperationData,
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OperationDataType,
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ShardingStrategy,
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StrategiesVector,
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TrainCycleItem,
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)
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from colossalai.fx.profiler.memory_utils import activation_size
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from colossalai.fx.profiler.opcount import flop_mapping
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from colossalai.tensor.sharding_spec import ShardingSpec
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from ..registry import meta_register
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__all__ = ['linear_meta_info']
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@meta_register.register(torch.nn.functional.linear)
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@meta_register.register(torch.nn.Linear)
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def linear_meta_info(*args, **kwargs) -> Tuple[TrainCycleItem, TrainCycleItem, List[torch.Tensor]]:
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"""torch.nn.Linear & torch.nn.functional.linear meta info generator
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NOTE: currently we separate the bias part from the biased linear ops, we will consider the memory consumption in add metainfo generator,
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but we will hold the bias mechanism in the linear metainfo generator for future use.
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graph():
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%input_2 : [#users=2] = placeholder[target=placeholder](default=)
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%addmm_default : [#users=1] = call_function[target=torch.ops.aten.addmm.default](args = (None, %input_2, None), kwargs = {})
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%zeros_like_default : [#users=3] = call_function[target=torch.ops.aten.zeros_like.default](args = (%addmm_default,), kwargs = {dtype: None, layout: None, device: None, pin_memory: None})
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%detach_default : [#users=1] = call_function[target=torch.ops.aten.detach.default](args = (%input_2,), kwargs = {})
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%mm_default : [#users=1] = call_function[target=torch.ops.aten.mm.default](args = (%zeros_like_default, None), kwargs = {})
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%t_default : [#users=1] = call_function[target=torch.ops.aten.t.default](args = (%zeros_like_default,), kwargs = {})
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%mm_default_1 : [#users=1] = call_function[target=torch.ops.aten.mm.default](args = (%t_default, %detach_default), kwargs = {})
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%t_default_1 : [#users=1] = call_function[target=torch.ops.aten.t.default](args = (%mm_default_1,), kwargs = {})
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%sum_dim_int_list : [#users=1] = call_function[target=torch.ops.aten.sum.dim_IntList](args = (%zeros_like_default, [None], None), kwargs = {})
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%view_default : [#users=1] = call_function[target=torch.ops.aten.view.default](args = (%sum_dim_int_list, [None]), kwargs = {})
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%detach_default_1 : [#users=1] = call_function[target=torch.ops.aten.detach.default](args = (%view_default,), kwargs = {})
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%detach_default_2 : [#users=0] = call_function[target=torch.ops.aten.detach.default](args = (%detach_default_1,), kwargs = {})
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%detach_default_3 : [#users=1] = call_function[target=torch.ops.aten.detach.default](args = (%mm_default,), kwargs = {})
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%detach_default_4 : [#users=0] = call_function[target=torch.ops.aten.detach.default](args = (%detach_default_3,), kwargs = {})
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%t_default_2 : [#users=1] = call_function[target=torch.ops.aten.t.default](args = (%t_default_1,), kwargs = {})
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%detach_default_5 : [#users=1] = call_function[target=torch.ops.aten.detach.default](args = (%t_default_2,), kwargs = {})
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%detach_default_6 : [#users=0] = call_function[target=torch.ops.aten.detach.default](args = (%detach_default_5,), kwargs = {})
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The one without bias is
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graph():
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%input_2 : [#users=2] = placeholder[target=placeholder](default=)
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%mm_default : [#users=1] = call_function[target=torch.ops.aten.mm.default](args = (%input_2, None), kwargs = {})
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%zeros_like_default : [#users=2] = call_function[target=torch.ops.aten.zeros_like.default](args = (%mm_default,), kwargs = {dtype: None, layout: None, device: None, pin_memory: None})
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%detach_default : [#users=1] = call_function[target=torch.ops.aten.detach.default](args = (%input_2,), kwargs = {})
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%t_default : [#users=1] = call_function[target=torch.ops.aten.t.default](args = (%zeros_like_default,), kwargs = {})
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%mm_default_1 : [#users=1] = call_function[target=torch.ops.aten.mm.default](args = (%t_default, %detach_default), kwargs = {})
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%t_default_1 : [#users=1] = call_function[target=torch.ops.aten.t.default](args = (%mm_default_1,), kwargs = {})
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%mm_default_2 : [#users=1] = call_function[target=torch.ops.aten.mm.default](args = (%zeros_like_default, None), kwargs = {})
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%detach_default_1 : [#users=1] = call_function[target=torch.ops.aten.detach.default](args = (%mm_default_2,), kwargs = {})
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%detach_default_2 : [#users=0] = call_function[target=torch.ops.aten.detach.default](args = (%detach_default_1,), kwargs = {})
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%t_default_2 : [#users=1] = call_function[target=torch.ops.aten.t.default](args = (%t_default_1,), kwargs = {})
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%detach_default_3 : [#users=1] = call_function[target=torch.ops.aten.detach.default](args = (%t_default_2,), kwargs = {})
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%detach_default_4 : [#users=0] = call_function[target=torch.ops.aten.detach.default](args = (%detach_default_3,), kwargs = {})
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Returns:
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Tuple[TrainCycleItem, TrainCycleItem, bool]: compute cost, memory cost and forward inputs
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"""
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has_bias: bool = False
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input_tensor = next(filter(lambda x: x.type == OperationDataType.ARG, args)).data
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output_tensor = next(filter(lambda x: x.type == OperationDataType.OUTPUT, args)).data
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weight_tensors = [x.data for x in args if x.type == OperationDataType.PARAM]
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# process the dimension of input and output
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if len(input_tensor.shape) > 2:
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input_tensor: torch.Tensor
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input_tensor = input_tensor.view(-1, input_tensor.shape[-1])
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if len(output_tensor.shape) > 2:
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output_tensor: torch.Tensor
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output_tensor = output_tensor.view(-1, output_tensor.shape[-1])
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if len(weight_tensors) > 1:
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has_bias = True
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if len(weight_tensors[0].shape) == 2:
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weight_tensor, bias_tensor = weight_tensors
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else:
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bias_tensor, weight_tensor = weight_tensors
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else:
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weight_tensor = weight_tensors[0]
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if has_bias:
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# calculate cost with bias
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# the fwd op with compute cost is addmm
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# the bwd op with compute cost is mm * 2 and sum.dim_IntList
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# calculate compute cost
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fwd_compute_cost = flop_mapping[torch.ops.aten.addmm.default](
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[bias_tensor, input_tensor, torch.transpose(weight_tensor, 0, 1)], (output_tensor,))
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bwd_compute_cost = flop_mapping[torch.ops.aten.mm.default]([output_tensor, weight_tensor], (input_tensor,)) + \
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flop_mapping[torch.ops.aten.mm.default]([torch.transpose(output_tensor, 0, 1), input_tensor], (weight_tensor,)) + \
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flop_mapping[torch.ops.aten.sum.dim_IntList]([output_tensor], (bias_tensor,))
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compute_cost = TrainCycleItem(fwd=fwd_compute_cost,
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bwd=bwd_compute_cost,
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total=fwd_compute_cost + bwd_compute_cost)
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# calculate memory cost
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# NOTE: Linear don't have buffer and temp in forward and backward phase
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# the forward activation cost is the size of output_tensor, parameter cost is the size of weight_tensor and bias_tensor
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# NOTE: currently in SPMD solver we always believe that there will be a new tensor created in forward
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fwd_memory_cost = MemoryCost(activation=activation_size([input_tensor, output_tensor]),
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parameter=activation_size([weight_tensor, bias_tensor]),
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temp=0,
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buffer=0)
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# the backward activation cost is the size of input_tensor, weight_tensor and bias_tensor, parameter cost is 0
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bwd_memory_cost = MemoryCost(activation=activation_size([input_tensor, weight_tensor, bias_tensor]),
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parameter=activation_size([weight_tensor, bias_tensor]),
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temp=0,
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buffer=0)
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# total cost is to sum the forward and backward cost
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total_cost = MemoryCost(activation=fwd_memory_cost.activation + bwd_memory_cost.activation,
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parameter=fwd_memory_cost.parameter + bwd_memory_cost.parameter)
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memory_cost = TrainCycleItem(fwd=fwd_memory_cost, bwd=bwd_memory_cost, total=total_cost)
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else:
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# calculate cost without bias
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# the fwd op with compute cost is mm
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# the bwd op with compute cost is mm * 2
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# calculate compute cost
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fwd_compute_cost = flop_mapping[torch.ops.aten.mm.default](
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[input_tensor, torch.transpose(weight_tensor, 0, 1)], (output_tensor,))
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bwd_compute_cost = flop_mapping[torch.ops.aten.mm.default]([output_tensor, weight_tensor], (input_tensor,)) + \
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flop_mapping[torch.ops.aten.mm.default]([torch.transpose(output_tensor, 0, 1), input_tensor], (weight_tensor,))
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compute_cost = TrainCycleItem(fwd=fwd_compute_cost,
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bwd=bwd_compute_cost,
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total=fwd_compute_cost + bwd_compute_cost)
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# calculate memory cost
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# NOTE: Linear don't have buffer and temp in forward and backward phase
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# the forward activation cost is the size of output_tensor, parameter cost is the size of weight_tensor
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# NOTE: currently in SPMD solver we always believe that there will be a new tensor created in forward
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fwd_memory_cost = MemoryCost(activation=activation_size(output_tensor),
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parameter=activation_size(weight_tensor),
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temp=0,
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buffer=0)
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# the backward activation cost is the size of input_tensor and weight_tensor, parameter cost is 0
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bwd_memory_cost = MemoryCost(activation=activation_size([input_tensor, weight_tensor]),
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parameter=activation_size(weight_tensor),
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temp=0,
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buffer=0)
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# total cost is to sum the forward and backward cost
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total_cost = MemoryCost(activation=fwd_memory_cost.activation + bwd_memory_cost.activation,
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parameter=fwd_memory_cost.parameter + bwd_memory_cost.parameter)
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memory_cost = TrainCycleItem(fwd=fwd_memory_cost, bwd=bwd_memory_cost, total=total_cost)
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# store fwd_in
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fwd_in = [input_tensor]
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return compute_cost, memory_cost, fwd_in
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