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207 lines
7.9 KiB
207 lines
7.9 KiB
from copy import deepcopy
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from dataclasses import dataclass
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from enum import Enum
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from typing import Any, Dict, List, Tuple, Union
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import torch
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from colossalai.tensor.shape_consistency import CommSpec
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from colossalai.tensor.sharding_spec import ShardingSpec
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from torch.fx.node import Node
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from .constants import (BCAST_FUNC_OP, ELEMENTWISE_FUNC_OP, ELEMENTWISE_MODULE_OP, RESHAPE_FUNC_OP)
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__all__ = ['OperationDataType', 'OperationData', 'TrainCycleItem', 'MemoryCost', 'ShardingStrategy', 'StrategiesVector']
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class OperationDataType(Enum):
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"""
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An operation can come from the argument list of an operator or the parameter list of a module.
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"""
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INPUT = 0
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ARG = 1
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PARAM = 2
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BUFFER = 3
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OUTPUT = 4
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@dataclass
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class OperationData:
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"""
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OperationData is the data related to an operator, the data can be the operand or the output.
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Args:
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name (str): the name of the operation-related data
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type (OperationDataType): the type of the operation data
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data (Any): the value for this data, usually it is a meta tensor.
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logical_shape (Tuple[int]): the logical shape of the data, it can be different from the its actual shape in memory.
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"""
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name: str
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type: OperationDataType
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data: Any
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logical_shape: Tuple[int] = None
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def __post_init__(self):
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# if no logical shape is specified, use the data shape as the logical shape
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if self.logical_shape is None and isinstance(self.data, torch.Tensor):
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self.logical_shape = self.data.shape
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def __repr__(self) -> str:
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return f'OperationData(name={self.name}, type={self.type})'
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def __eq__(self, other) -> bool:
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return other.name == self.name
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def __hash__(self) -> int:
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return hash(f'{self.name}')
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@dataclass
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class TrainCycleItem:
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"""
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TrainCycleItem is a dataclass to store the items which have different values for the forward and backward pass
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in a training iteration.
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Args:
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fwd (float): the item for the forward pass
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bwd (float): the item for the backward pass
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"""
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fwd: Any
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bwd: Any
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total: Any
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@dataclass
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class MemoryCost:
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"""
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MemoryCost is a dataclass which stores the memory usage in the program.
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Args:
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activation (int): the memory cost incurred by the activations in bytes.
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parameter (int): the memory cost incurred by the module parameter in bytes.
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"""
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activation: int = 0
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parameter: int = 0
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buffer: int = 0
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@dataclass
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class ShardingStrategy:
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"""
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ShardingStrategy is a dataclass to store the meta information on tensor sharding for a node.
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Args:
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name (str): express the sharding strategies in string, such as 'S0S1 = S0R x RS1'.
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output_sharding_spec (ShardingSpec): ShardingSpec of the output node.
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compute_cost (TrainCycleItem): Computation cost to complete this strategy. (default to None)
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communication_cost (TrainCycleItem): Communication cost to complete this strategy. (default to None)
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memory_cost (TrainCycleItem): Memory cost of the output node using this strategy. (default to None)
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input_sharding_specs (List(ShardingSpec)): The ShardingSpecs of the input nodes.
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"""
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name: str
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sharding_specs: Dict[OperationData, Union[ShardingSpec, Tuple[ShardingSpec]]] = None
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compute_cost: TrainCycleItem = None
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communication_cost: TrainCycleItem = None
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memory_cost: TrainCycleItem = None
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communication_actions: Dict[OperationData, CommSpec] = None
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resharding_costs: Dict[Node, List[TrainCycleItem]] = None
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@property
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def input_sharding_specs(self) -> Dict[OperationData, ShardingSpec]:
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specs = {}
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specs.update(self._get_sharding_spec(OperationDataType.ARG))
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specs.update(self._get_sharding_spec(OperationDataType.PARAM))
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return specs
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@property
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def argument_sharding_specs(self) -> Dict[OperationData, ShardingSpec]:
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return self._get_sharding_spec(OperationDataType.ARG)
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@property
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def param_sharding_specs(self) -> Dict[OperationData, ShardingSpec]:
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return self._get_sharding_spec(OperationDataType.PARAM)
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@property
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def output_sharding_specs(self) -> Dict[OperationData, ShardingSpec]:
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return self._get_sharding_spec(OperationDataType.OUTPUT)
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def _get_sharding_spec(self, operation_data_type: OperationDataType):
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specs = {k: v for k, v in self.sharding_specs.items() if k.type == operation_data_type}
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return specs
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def get_op_data_by_name(self, name: str):
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for op_data in self.sharding_specs.keys():
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if op_data.name == name:
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return op_data
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raise KeyError(f"Could not find the OperationData with name {name}")
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def get_sharding_spec_by_name(self, name: str):
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for op_data, sharding_spec in self.sharding_specs.items():
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if op_data.name == name:
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return sharding_spec
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raise KeyError(f"Could not find the ShardingSpec for OperationData with name {name}")
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def clone(self):
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def _deepcopy_dict_vals(data: Dict):
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return {k: deepcopy(v) for k, v in data.items()}
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sharding_specs = _deepcopy_dict_vals(self.sharding_specs) if self.sharding_specs else None
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communication_actions = _deepcopy_dict_vals(self.communication_actions) if self.communication_actions else None
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resharding_costs = _deepcopy_dict_vals(self.resharding_costs) if self.resharding_costs else None
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compute_cost = deepcopy(self.compute_cost)
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communication_cost = deepcopy(self.communication_cost)
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memory_cost = deepcopy(self.memory_cost)
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return ShardingStrategy(name=self.name,
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sharding_specs=sharding_specs,
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compute_cost=compute_cost,
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communication_cost=communication_cost,
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memory_cost=memory_cost,
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communication_actions=communication_actions,
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resharding_costs=resharding_costs)
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class StrategiesVector(list):
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'''
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Each node in fx graph will have a corresponding StrategiesVector, to store all the possible
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strategies of the node.
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Argument:
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node (Node): node for which the list of sharding strategies are generated.
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'''
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def __init__(self, node: Node):
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super().__init__()
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self.node = node
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# fetch its input and output nodes
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# TODO: placeholder input nodes
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self.predecessor_nodes = list(node._input_nodes.keys())
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if self.node.op == 'output':
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self.predecessor_nodes = list(node._input_nodes.keys())[:1]
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self.successor_nodes = list(node.users.keys())
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def check_merge(self):
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merge_label = False
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if self.node.op == 'call_module':
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target = self.node.target
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root_module = self.node.graph.owning_module
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submod = root_module.get_submodule(target)
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submod_type = type(submod)
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# merge elementwise module node into source nodes
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# we could merge element-wise op, because the output sharding spec is always same as the input sharding spec.
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if submod_type in ELEMENTWISE_MODULE_OP:
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merge_label = True
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if self.node.op == 'call_function':
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# we could merge element-wise op, because the output sharding spec is always same as the input sharding spec.
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if self.node.target in ELEMENTWISE_FUNC_OP:
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merge_label = True
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# we could merge bcast op if the rhs is a scalar, because it will fall back to the element-wise case.
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if self.node.target in BCAST_FUNC_OP and len(self.predecessor_nodes) == 1:
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merge_label = True
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# we could merge reshape op, because the output sharding spec of reshape op is always fully replicated.
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if self.node.target in RESHAPE_FUNC_OP:
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merge_label = True
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return merge_label
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