mirror of https://github.com/hpcaitech/ColossalAI
185 lines
4.8 KiB
Python
185 lines
4.8 KiB
Python
import math
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from abc import ABC
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from typing import Any, Iterable, List
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from torch.utils._pytree import tree_map
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class Chain:
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def __init__(self,
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ftime: List[float],
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btime: List[float],
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x: List[int],
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xbar: List[int],
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ftmp: List[int],
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btmp: List[int],
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check_consistency: bool = True):
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"""The chain is a basic linearized structure for solving the dynamic programming problem for activation checkpoint.
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See paper https://hal.inria.fr/hal-02352969 for details.
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Args:
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ftime (List[float]): The forward time of each node.
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btime (List[float]): The backward time of each node.
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x (List[int]): The forward memory of each node (if save_output). Same as `a` in the paper.
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xbar (List[int]): The forward memory of each node (if save_all). Same as `a_bar` in the paper.
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ftmp (List[int]): The temporary forward memory of each node.
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btmp (List[int]): The temporary backward memory of each node, can be used to control memory budget.
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check_consistency (bool, optional): Check the lengths consistency for the `Chain`. Defaults to True.
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"""
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self.ftime = ftime
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self.btime = btime
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self.x = x
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self.xbar = xbar
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self.ftmp = ftmp
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self.btmp = btmp
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if check_consistency and not self.check_lengths():
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raise AttributeError("In Chain, input lists do not have consistent lengths")
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def check_lengths(self):
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return ((len(self.ftime) == len(self)) and (len(self.btime) == len(self) + 1) and (len(self.x) == len(self) + 1)
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and (len(self.ftmp) == len(self)) and (len(self.btmp) == len(self) + 1)
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and (len(self.xbar) == len(self) + 1))
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def __repr__(self):
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chain_list = []
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for i in range(len(self)):
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chain_list.append((self.ftime[i], self.btime[i], self.x[i], self.xbar[i], self.ftmp[i], self.btmp[i]))
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i = len(self)
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chain_list.append((None, self.btime[i], self.x[i], self.xbar[i], None, self.btmp[i]))
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return chain_list.__repr__()
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def __len__(self):
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return len(self.ftime)
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def discretize_all(self, unit: int):
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"""Discretize the chain into a list of chains according to unit size."""
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discretizer = lambda val: math.ceil(val / unit)
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self.x = tree_map(discretizer, self.x)
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self.xbar = tree_map(discretizer, self.xbar)
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self.ftmp = tree_map(discretizer, self.ftmp)
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self.btmp = tree_map(discretizer, self.btmp)
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class Operation(ABC):
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name = "Op"
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def __repr__(self) -> str:
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return f"{self.name}_{self.index}"
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def shift(self, value):
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if type(self.index) is tuple:
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self.index = tuple(x + value for x in self.index)
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else:
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self.index += value
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class Forward(Operation):
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name = "F"
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def __init__(self, index):
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self.index = index
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def cost(self, chain: Chain):
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if chain is not None:
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return chain.ftime[self.index]
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else:
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return 1
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class ForwardEnable(Forward):
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name = "Fe"
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class ForwardNograd(Forward):
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name = "Fn"
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class ForwardCheck(Forward):
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name = "CF"
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class Forwards(Operation):
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def __init__(self, start, end):
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self.index = (start, end)
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def __repr__(self):
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return "F_{i}->{j}".format(i=self.index[0], j=self.index[1])
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def cost(self, chain: Chain):
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if chain is not None:
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return sum(chain.ftime[self.index[0]:self.index[1] + 1])
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else:
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return (self.index[1] - self.index[0] + 1)
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def isForward(op):
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return type(op) is Forward or type(op) is Forwards
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class Backward(Operation):
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name = "B"
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def __init__(self, index):
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self.index = index
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def cost(self, chain: Chain):
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if chain is not None:
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return chain.btime[self.index]
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else:
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return 1
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class Loss(Operation):
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def __init__(self):
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pass
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def __repr__(self):
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return "L"
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def cost(self, chain):
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return 0
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class MemoryAccess(Operation):
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name = "MA"
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def __init__(self, index):
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self.index = index
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def cost(self, chain: Chain):
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return 0
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class WriteMemory(MemoryAccess):
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name = "WM"
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class ReadMemory(MemoryAccess):
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name = "RM"
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class DiscardMemory(MemoryAccess):
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name = "DM"
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class Sequence(list):
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def __init__(self):
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super().__init__()
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def __repr__(self):
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return repr(self.list_operations())
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def list_operations(self):
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op_list = []
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for x in self:
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if isinstance(x, Operation):
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op_list.append(x)
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else:
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assert isinstance(x, Sequence)
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op_list += x.list_operations()
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return op_list
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