# mypy: allow-untyped-defs import io from typing import Any, Callable, cast, Dict, List import torch import torch.distributed as dist from torch._utils import _get_device_module from torch.distributed._shard.metadata import ShardMetadata from torch.distributed._shard.sharded_tensor import ShardedTensor from torch.distributed.tensor import DTensor from torch.distributed.tensor._utils import compute_local_shape_and_global_offset from .metadata import ( BytesStorageMetadata, ChunkStorageMetadata, MetadataIndex, STATE_DICT_TYPE, STORAGE_TYPES, TensorProperties, TensorStorageMetadata, ) from .planner import ( LoadItemType, ReadItem, SavePlan, TensorWriteData, WriteItem, WriteItemType, ) from .resharding import ( _check_shard_metadata_pair_overlap, _shards_get_overlap_region_wrt_saved_tensor, ) __all__: List[str] = ["create_read_items_for_chunk_list"] def _create_chunk_from_tensor(tensor: torch.Tensor) -> ChunkStorageMetadata: return ChunkStorageMetadata( offsets=torch.Size([0] * len(tensor.size())), sizes=tensor.size() ) def _chunk_for_shard(shard_md: ShardMetadata) -> ChunkStorageMetadata: return ChunkStorageMetadata( offsets=torch.Size(shard_md.shard_offsets), sizes=torch.Size(shard_md.shard_sizes), ) def _sharded_tensor_metadata( sharded_tensor: ShardedTensor, shard_md: ShardMetadata ) -> TensorWriteData: shard_properties = sharded_tensor.metadata().tensor_properties properties = TensorProperties( dtype=shard_properties.dtype, layout=shard_properties.layout, requires_grad=shard_properties.requires_grad, memory_format=shard_properties.memory_format, pin_memory=shard_properties.pin_memory, ) return TensorWriteData( chunk=_chunk_for_shard(shard_md), properties=properties, size=sharded_tensor.metadata().size, ) def _create_write_items_for_dtensor(fqn: str, tensor: DTensor) -> WriteItem: sizes, offsets = compute_local_shape_and_global_offset( tensor.shape, tensor.device_mesh, tensor.placements ) sizes, offsets = torch.Size(sizes), torch.Size(offsets) return WriteItem( index=MetadataIndex(fqn, offsets), type=WriteItemType.SHARD, tensor_data=TensorWriteData( chunk=ChunkStorageMetadata( offsets=offsets, sizes=sizes, ), properties=TensorProperties.create_from_tensor(tensor.to_local()), size=tensor.size(), ), ) def _create_write_item_for_shard( fqn: str, sharded_tensor: ShardedTensor, shard_md: ShardMetadata ) -> WriteItem: offsets = torch.Size(shard_md.shard_offsets) return WriteItem( index=MetadataIndex(fqn, offsets), type=WriteItemType.SHARD, tensor_data=_sharded_tensor_metadata(sharded_tensor, shard_md), ) def _create_write_item_for_tensor(fqn: str, tensor: torch.Tensor) -> WriteItem: offsets = torch.Size([0] * len(tensor.size())) return WriteItem( index=MetadataIndex(fqn, offsets), type=WriteItemType.TENSOR, tensor_data=TensorWriteData( chunk=ChunkStorageMetadata(offsets=offsets, sizes=tensor.size()), properties=TensorProperties.create_from_tensor(tensor), size=tensor.size(), ), ) def _create_write_item_for_bytesio(fqn: str, bytes: Any): return WriteItem( index=MetadataIndex(fqn), type=WriteItemType.BYTE_IO, ) def _create_read_item_for_byteio( dest_index, dest_offset, storage_index, storage_offset, length ): return ReadItem( type=LoadItemType.BYTE_IO, dest_index=dest_index, dest_offsets=torch.Size((dest_offset,)), storage_index=storage_index, storage_offsets=torch.Size((storage_offset,)), lengths=torch.Size((length,)), ) def _create_read_item_for_tensor( dest_index, dest_offsets, storage_index, storage_offsets, lengths ): return ReadItem( type=LoadItemType.TENSOR, dest_index=dest_index, dest_offsets=torch.Size(dest_offsets), storage_index=storage_index, storage_offsets=torch.Size(storage_offsets), lengths=torch.Size(lengths), ) def create_read_items_for_chunk_list( fqn: str, checkpoint_md: TensorStorageMetadata, local_chunks: List[ChunkStorageMetadata], ) -> List[ReadItem]: """ Create a list of ``ReadItem`` based on the checkpoint and local chunks. This applies the resharding algorithm and computes the reads needed to satisfy ``local_chunks`` with a checkpoint described by ``checkpoint_md``. Args: fqn (str) : The state_dict FQN to pass to ``ReadItem``. checkpoint_md (TensorStorageMetadata): metadata for a given tensor from a checkpoint. local_chunks (List[ChunkStorageMetadata]): Local chunks that needs to be loaded. Returns: A list of ``ReadItem`` that will satisfy all input chunks. """ read_items = [] # this is a naive quadratic algo that can be optimized later for idx, shard in enumerate(local_chunks): for storage_idx, storage_md in enumerate(checkpoint_md.chunks): if not _check_shard_metadata_pair_overlap(shard, storage_md): continue storage_offsets = [] dest_offsets = [] lengths = [] for ( dim, offset_for_saved_tensor, offset_for_current_tensor, length, ) in _shards_get_overlap_region_wrt_saved_tensor( saved_shard=storage_md, current_shard=shard ): storage_offsets.append(offset_for_saved_tensor) dest_offsets.append(offset_for_current_tensor) lengths.append(length) read_items.append( _create_read_item_for_tensor( dest_index=MetadataIndex(fqn, shard.offsets, idx), dest_offsets=dest_offsets, storage_index=MetadataIndex(fqn, storage_md.offsets, storage_idx), storage_offsets=storage_offsets, lengths=lengths, ) ) return read_items def _create_default_metadata_only_plan(state_dict: STATE_DICT_TYPE) -> SavePlan: requests = [] for fqn, obj in state_dict.items(): if isinstance(obj, DTensor): requests.append(_create_write_items_for_dtensor(fqn, obj)) elif isinstance(obj, ShardedTensor): for shard_md in obj.metadata().shards_metadata: requests.append(_create_write_item_for_shard(fqn, obj, shard_md)) elif isinstance(obj, torch.Tensor): requests.append(_create_write_item_for_tensor(fqn, obj)) else: requests.append(_create_write_item_for_bytesio(fqn, obj)) return SavePlan(requests) def _create_write_items(fqn: str, object: Any) -> List[WriteItem]: if hasattr(object, "__create_write_items__"): # DTensor implements _Checkpointable return object.__create_write_items__(fqn, object) elif isinstance(object, ShardedTensor): return [ _create_write_item_for_shard(fqn, object, shard.metadata) for shard in object.local_shards() ] elif isinstance(object, torch.Tensor): return [_create_write_item_for_tensor(fqn, object)] else: return [_create_write_item_for_bytesio(fqn, object)] def _create_chunk_from_dtensor(tensor: DTensor) -> ChunkStorageMetadata: sizes, offsets = compute_local_shape_and_global_offset( tensor.shape, tensor.device_mesh, tensor.placements ) sizes, offsets = torch.Size(sizes), torch.Size(offsets) return ChunkStorageMetadata( offsets=offsets, sizes=sizes, ) def _create_chunk_list(tensor: torch.Tensor) -> List[ChunkStorageMetadata]: if hasattr(tensor, "__create_chunk_list__"): # DTensor implements _Checkpointable local_chunks = tensor.__create_chunk_list__() # type: ignore[attr-defined] elif isinstance(tensor, ShardedTensor): local_chunks = [ _chunk_for_shard(shard.metadata) for shard in tensor.local_shards() ] elif isinstance(tensor, torch.Tensor): local_chunks = [_create_chunk_from_tensor(tensor)] else: raise ValueError( "Unsupported Type, expecting one of [Tensor, DTensor, ShardedTensor] " f",but got {type(tensor)}" ) return local_chunks def _create_read_items(fqn: str, md: STORAGE_TYPES, obj: Any) -> List[ReadItem]: if not isinstance(md, BytesStorageMetadata): try: local_chunks = _create_chunk_list(obj) except ValueError as ex: raise ValueError( f"Invalid checkpoint metadata for {fqn}, " + f"expected BytesStorageMetadata but found {type(md)}", ) from ex return create_read_items_for_chunk_list(fqn, md, local_chunks) else: return [ _create_read_item_for_byteio( dest_index=MetadataIndex(fqn), dest_offset=0, storage_index=MetadataIndex(fqn), storage_offset=0, length=0, ) ] def _init_state_dict(state_dict: Dict[str, Any]) -> Any: """ Initializes meta tensor if the meta tensor is DTensor or torch.Tensor. """ def dtensor_func(value: DTensor): device = getattr(value, "device", None) if device == torch.device("meta"): device_type = dist.distributed_c10d._get_pg_default_device().type device = cast( torch.device, _get_device_module(device_type).current_device() ) new_local_tensor = torch.empty_like(value.to_local(), device=device) # We need to pass shape and stride explicitly, since DTensor might be # sharded unevenly. dtensor = DTensor.from_local( new_local_tensor, device_mesh=value.device_mesh, placements=value.placements, shape=value.size(), stride=value.stride(), ) return dtensor else: return value def sharded_tensor_func(value: Any): device = getattr(value, "device", None) if device == torch.device("meta"): raise RuntimeError( f"Found unsupported type {type(value)} for meta device loading." ) else: return value def tensor_func(value: torch.Tensor): device = getattr(value, "device", None) if device == torch.device("meta"): device_type = dist.distributed_c10d._get_pg_default_device().type device = cast( torch.device, _get_device_module(device_type).current_device() ) tensor = torch.empty_like(value, device=device) return tensor else: return value _iterate_state_dict( state_dict, dtensor_func, sharded_tensor_func, tensor_func, ) def _iterate_state_dict( iter_object: Any, dtensor_func: Callable, sharded_tensor_func: Callable, tensor_func: Callable, ): """ Iterate through the state dict, applying the given functions to each tensor type and update the state dict in place. Args: iter_object (Any): the target state_dict. sharded_tensor_func (Callable): the function to apply to ShardedTensor dtensor_func (Callable): the function to apply to DTensor tensor_func (Callable): the function to apply to Tensor # TODO: let state_dict_util._iterate_state_dict() to support in place option so we don't need to have two versions of _iterate_state_dict. """ if isinstance(iter_object, DTensor): return dtensor_func(iter_object) elif isinstance(iter_object, ShardedTensor): return sharded_tensor_func(iter_object) elif isinstance(iter_object, torch.Tensor): return tensor_func(iter_object) elif ( isinstance(iter_object, (int, float, str, bytes, io.BytesIO)) or iter_object is None ): return iter_object elif isinstance(iter_object, dict): for key, value in iter_object.items(): iter_object[key] = _iterate_state_dict( value, dtensor_func, sharded_tensor_func, tensor_func ) return iter_object elif isinstance(iter_object, (list, tuple)): ret = [ _iterate_state_dict(v, dtensor_func, sharded_tensor_func, tensor_func) for v in iter_object ] if isinstance(iter_object, tuple): ret = tuple(ret) # type: ignore[assignment] return ret