ColossalAI/colossalai/zero/gemini/placement_policy.py

import functools
import warnings
from abc import ABC, abstractmethod
from time import time
from typing import Dict, List, Optional, Tuple, Type

import torch

from colossalai.accelerator import get_accelerator
from colossalai.legacy.utils.memory import colo_device_memory_capacity
from colossalai.zero.gemini.chunk import Chunk

from .chunk import Chunk, ChunkManager
from .memory_tracer import ChunkMemStatsCollector


class PlacementPolicy(ABC):
    need_mem_stats: bool = False

    def __init__(
        self, chunk_manager: ChunkManager, mem_stats_collector: Optional[ChunkMemStatsCollector] = None, **kwargs
    ) -> None:
        self.chunk_manager = chunk_manager
        self.mem_stats_collector: Optional[ChunkMemStatsCollector] = mem_stats_collector

    @abstractmethod
    def evict_tensors(self, can_evict_chunks: List[Chunk], **kwargs) -> Tuple[int, float]:
        raise NotImplementedError

    @abstractmethod
    def setup_grads_device(
        self, params: List[torch.Tensor], grads_device_map: Dict[torch.Tensor, torch.device]
    ) -> None:
        raise NotImplementedError


class StaticPlacementPolicy(PlacementPolicy):
    def __init__(
        self,
        chunk_manager: ChunkManager,
        mem_stats_collector: Optional[ChunkMemStatsCollector] = None,
        shard_param_frac: float = 1.0,
        offload_optim_frac: float = 0.0,
        offload_param_frac: float = 0.0,
        **kwargs,
    ) -> None:
        super().__init__(chunk_manager, mem_stats_collector=mem_stats_collector)
        if offload_param_frac > 0.0 and (shard_param_frac != 1.0 or offload_optim_frac != 1.0):
            warnings.warn("offload_param_frac is ignored when shard_param_frac != 1.0 or offload_optim_frac != 1.0")
            offload_param_frac = 0.0
        self.shard_param_frac = shard_param_frac
        self.offload_optim_frac = offload_optim_frac
        self.offload_param_frac = offload_param_frac
        # these should be initialized in setup_grads_device
        self.keep_gathered_chunk_mem = 0.0
        self.keep_cuda_chunk_mem = 0.0

    def evict_tensors(self, can_evict_chunks: List[Chunk], **kwargs) -> Tuple[int, float]:
        can_shard_chunk_mem = sum(chunk.chunk_mem for chunk in can_evict_chunks)
        can_offload_chunk_mem = can_shard_chunk_mem
        for chunk in can_evict_chunks:
            if can_shard_chunk_mem <= self.keep_gathered_chunk_mem:
                break
            self.chunk_manager.release_chunk(chunk)
            # real saved mem is chunk_mem - shard_mem, for simplicity we use chunk_mem
            can_shard_chunk_mem -= chunk.chunk_mem
        for chunk in can_evict_chunks:
            if can_offload_chunk_mem <= self.keep_cuda_chunk_mem:
                break
            self.chunk_manager.move_chunk(chunk, torch.device("cpu"))
            # real saved mem is shard_mem, for simplicity we use chunk_mem
            can_offload_chunk_mem -= chunk.chunk_mem
        return 0, 0.0

    def setup_grads_device(
        self, params: List[torch.Tensor], grads_device_map: Dict[torch.Tensor, torch.device]
    ) -> None:
        total_chunk_mem = sum(self.chunk_manager.get_chunk(p).chunk_mem for p in params)

        offload_optim_chunk_mem = total_chunk_mem * self.offload_optim_frac
        offloaded_optim_chunk_mem = 0
        chunks = set(self.chunk_manager.get_chunk(p) for p in params)
        for chunk in chunks:
            params = chunk.get_tensors()
            # init offload optim settings
            # keep gathered chunks are in CUDA
            if chunk.keep_gathered or offloaded_optim_chunk_mem >= offload_optim_chunk_mem:
                device = get_accelerator().get_current_device()
            else:
                device = torch.device("cpu")
                # real offloaded mem is chunk.shard_mem, for simplicity we use chunk mem here
                offloaded_optim_chunk_mem += chunk.chunk_mem
            for p in params:
                grads_device_map[p] = device
        self.keep_gathered_chunk_mem = total_chunk_mem * (1 - self.shard_param_frac)
        self.keep_cuda_chunk_mem = total_chunk_mem * (1 - self.offload_param_frac)


class AutoPlacementPolicy(PlacementPolicy):
    need_mem_stats: bool = True

    def __init__(
        self,
        chunk_manager: ChunkManager,
        mem_stats_collector: Optional[ChunkMemStatsCollector] = None,
        warmup_non_model_data_ratio: float = 0.8,
        steady_cuda_cap_ratio: float = 0.9,
        **kwargs,
    ) -> None:
        super().__init__(chunk_manager, mem_stats_collector=mem_stats_collector)
        # model data will use 1-_warmup_non_model_data_ratio CUDA memory in warmup phase
        # you can set them by AutoPlacementPolicy.set_warmup_non_model_data_ratio()
        # and AutoPlacementPolicy.set_steady_cuda_cap_ratio()
        self._warmup_non_model_data_ratio = warmup_non_model_data_ratio
        self._steady_cuda_cap_ratio = steady_cuda_cap_ratio

    def evict_tensors(
        self,
        can_evict_chunks: List[Chunk],
        cuda_demand: int = 0,
        warmup: bool = True,
        compute_list: Optional[List[Tuple[Chunk, ...]]] = None,
        compute_idx: int = 0,
        **kwargs,
    ) -> Tuple[int, float]:
        """
        Evict tensors from CUDA device.

        Args:
            can_evict_chunks (List[StatefulTensor]): the list of tensors that can be evicted.
            cuda_demand (int, optional): the volume of data needed on cuda device. Defaults to 0.
            warmup (bool, optional): a flag indicates whether in the phase of warmup. Defaults to True.
            compute_list (List[StatefulTensor], optional): TODO. Defaults to [].
            compute_idx (int, optional): the idx of computing device. Defaults to 0.

        Raises:
            RuntimeError:

        Returns:
            int: the volume of memory that is evicted
        """
        start = time()
        cuda_capacity = colo_device_memory_capacity(get_accelerator().get_current_device())
        used_cuda_model_data = self.chunk_manager.total_mem["cuda"]
        if warmup:
            # We designate a part of CUDA memory for model data in warmup iterations.
            max_cuda_non_model_data_per_period = cuda_capacity * self._warmup_non_model_data_ratio
        else:
            # max non-model-data cuda memory consumption of this sampling moment and the next sampling moment.
            max_cuda_non_model_data_per_period = self.mem_stats_collector.next_period_non_model_data_usage("cuda")
            cuda_capacity *= self._steady_cuda_cap_ratio
        total_cuda_model_data = cuda_capacity - max_cuda_non_model_data_per_period
        avail_cuda_model_data = total_cuda_model_data - used_cuda_model_data
        freed_cuda_model_data = 0

        if avail_cuda_model_data < cuda_demand:
            # Move cuda_demand - avail_cuda_model_data volume of tensors
            # to_free_cuda_model_data = cuda_demand - avail_cuda_model_data
            to_free_cuda_model_data = cuda_demand - avail_cuda_model_data
            to_free_chunks = can_evict_chunks
            if not warmup:
                to_free_chunks = self._sort_can_evict_chunks(tuple(to_free_chunks), compute_idx, tuple(compute_list))
                # print(self._sort_can_evict_chunks.cache_info())
            for chunk in to_free_chunks:
                if freed_cuda_model_data >= to_free_cuda_model_data:
                    break

                self.chunk_manager.release_chunk(chunk)
                self.chunk_manager.move_chunk(chunk, torch.device("cpu"))
                freed_cuda_model_data += chunk.chunk_mem
            if freed_cuda_model_data < to_free_cuda_model_data:
                raise RuntimeError(
                    f"Adjust layout failed! No enough CUDA memory! "
                    f"Need {to_free_cuda_model_data}, freed {freed_cuda_model_data}"
                )
        return freed_cuda_model_data, time() - start

    @staticmethod
    @functools.lru_cache(maxsize=None)
    def _sort_can_evict_chunks(can_evict_chunks: tuple, compute_idx: int, compute_list: tuple) -> list:
        next_compute_idx = {chunk: len(compute_list) for chunk in can_evict_chunks}
        for i in range(len(compute_list) - 1, compute_idx, -1):
            for chunk in compute_list[i]:
                if chunk in next_compute_idx:
                    next_compute_idx[chunk] = i
        next_compute_idx = sorted(next_compute_idx.items(), key=lambda pair: pair[1], reverse=True)
        return [t for (t, idx) in next_compute_idx]

    def setup_grads_device(
        self, params: List[torch.Tensor], grads_device_map: Dict[torch.Tensor, torch.device]
    ) -> None:
        for p in params:
            chunk = self.chunk_manager.get_chunk(p)
            # init offload optim settings
            # keep gathered chunks are in CUDA
            if chunk.keep_gathered:
                grads_device_map[p] = get_accelerator().get_current_device()
            else:
                grads_device_map[p] = torch.device("cpu")


class PlacementPolicyFactory:
    policies: Dict[str, Type[PlacementPolicy]] = {
        "auto": AutoPlacementPolicy,
        "static": StaticPlacementPolicy,
    }

    @staticmethod
    def create(policy_name: str) -> Type[PlacementPolicy]:
        if policy_name not in PlacementPolicyFactory.policies:
            raise TypeError(f"Unknown tensor placement policy {policy_name}")
        return PlacementPolicyFactory.policies[policy_name]

    @staticmethod
    def get_policy_names():
        return tuple(PlacementPolicyFactory.policies.keys())