[DTensor] refactor CommSpec (#3034)

2025-06-24 14:33:20 +00:00 · 2023-03-08 10:45:31 +08:00 · 2023-03-08 10:45:31 +08:00 · 29386a54e6
commit 29386a54e6
parent ea0b52c12e
3 changed files with 501 additions and 1 deletions
--- a/colossalai/tensor/d_tensor/comm_spec.py
+++ b/colossalai/tensor/d_tensor/comm_spec.py
@ -0,0 +1,310 @@
 from enum import Enum
 from typing import Dict
 import torch
 import torch.distributed as dist
 from torch.distributed import ReduceOp
 __all__ = [
    'CollectiveCommPattern',
    'CommSpec',
 ]
 class CollectiveCommPattern(Enum):
    GATHER_FWD_SPLIT_BWD = 'gather_fwd_split_bwd'
    ALL2ALL_FWD_ALL2ALL_BWD = 'all2all_fwd_all2all_bwd'
    SPLIT_FWD_GATHER_BWD = 'split_fwd_gather_bwd'
    ALLREDUCE_FWD_IDENTITY_BWD = 'all_reduce_fwd_identity_bwd'
    IDENTITY_FWD_ALLREDUCE_BWD = 'identity_fwd_all_reduce_bwd'
    MIXGATHER_FWD_SPLIT_BWD = "mixgather_fwd_split_bwd"
 class CommSpec:
    '''
    Communication spec is used to record the communication action. It converts the communication spec
    to real action which will be used in runtime. It contains comm_pattern to determine the
    communication method, process_groups_dict to determine the process groups, gather_dim and shard_dim
    to determine the buffer shape, and logical_process_axis
    Argument:
        comm_pattern(CollectiveCommPattern): decribe the communication method used in this spec.
        process_groups_dict(Dict): A dict which contains the process groups used to apply this CommSpec.
        gather_dim(int, Optional): The gather_dim of the tensor will be gathered.
        shard_dim(int, Optional): The shard_dim of the tensor will be sharded.
        logical_process_axis(Union(int, List[int]), Optional): The mesh_dim to implement the communication action.
    '''
    def __init__(self,
                 comm_pattern: CollectiveCommPattern,
                 process_groups_dict: Dict,
                 gather_dim: int = None,
                 shard_dim: int = None,
                 logical_process_axis: int = None):
        self.comm_pattern = comm_pattern
        self.gather_dim = gather_dim
        self.shard_dim = shard_dim
        self.logical_process_axis = logical_process_axis
        self.process_groups_dict = process_groups_dict
    def __repr__(self):
        res_list = ["CommSpec:("]
        if self.comm_pattern == CollectiveCommPattern.GATHER_FWD_SPLIT_BWD:
            res_list.append(f"comm_pattern:GATHER_FWD_SPLIT_BWD, ")
            res_list.append(f"gather_dim:{self.gather_dim}, ")
            res_list.append(f"shard_dim:{self.gather_dim}, ")
            res_list.append(f"logical_process_axis:{self.logical_process_axis})")
        elif self.comm_pattern == CollectiveCommPattern.ALL2ALL_FWD_ALL2ALL_BWD:
            res_list.append(f"comm_pattern:ALL2ALL_FWD_ALL2ALL_BWD, ")
            res_list.append(f"gather_dim:{self.gather_dim}, ")
            res_list.append(f"shard_dim:{self.shard_dim}, ")
            res_list.append(f"logical_process_axis: {self.logical_process_axis})")
        elif self.comm_pattern == CollectiveCommPattern.SPLIT_FWD_GATHER_BWD:
            res_list.append(f"comm_pattern:SPLIT_FWD_GATHER_BWD, ")
            res_list.append(f"gather_dim:{self.gather_dim}, ")
            res_list.append(f"shard_dim:{self.shard_dim}, ")
            res_list.append(f"logical_process_axis:{self.logical_process_axis})")
        elif self.comm_pattern == CollectiveCommPattern.ALLREDUCE_FWD_IDENTITY_BWD:
            res_list.append(f"comm_pattern:ALLREDUCE_FWD_IDENTITY_BWD, ")
            res_list.append(f"logical_process_axis:{self.logical_process_axis})")
        elif self.comm_pattern == CollectiveCommPattern.IDENTITY_FWD_ALLREDUCE_BWD:
            res_list.append(f"comm_pattern:IDENTITY_FWD_ALLREDUCE_BWD, ")
            res_list.append(f"logical_process_axis:{self.logical_process_axis})")
        return ''.join(res_list)
    def covert_spec_to_action(self, tensor):
        '''
        Convert CommSpec into runtime action, implement real collection communication to target tensor.
        The collection communication action is directed by the CommSpec.
        Argument:
            tensor(torch.Tensor): Tensor stored in each device, which could be different in different ranks.
        '''
        if self.comm_pattern in pattern_to_func_dict:
            tensor = pattern_to_func_dict[self.comm_pattern](tensor, self)
        else:
            tensor = tensor
        return tensor
 def _all_gather(tensor: torch.Tensor, comm_spec: CommSpec):
    '''
    Implement all gather operation on device mesh based on information provided by comm_spec.
    '''
    process_groups_list = comm_spec.process_groups_dict[comm_spec.logical_process_axis]
    for rank_list, process_group in process_groups_list:
        if dist.get_rank() in rank_list:
            tensor_list = [
                torch.zeros(tensor.shape, dtype=tensor.dtype, device=tensor.device) for _ in range(len(rank_list))
            ]
            # without this contiguous operation, the all gather may get some unexpected results.
            tensor = tensor.contiguous()
            dist.all_gather(tensor_list, tensor, group=process_group)
            output = torch.cat(tuple(tensor_list), comm_spec.gather_dim).contiguous()
            return output
 def _split(tensor: torch.Tensor, comm_spec: CommSpec):
    '''
    Implement shard operation on device mesh based on information provided by comm_spec.
    '''
    process_groups_list = comm_spec.process_groups_dict[comm_spec.logical_process_axis]
    for rank_list, _ in process_groups_list:
        if dist.get_rank() in rank_list:
            dim = comm_spec.shard_dim
            length = tensor.shape[comm_spec.shard_dim] // len(rank_list)
            start = length * rank_list.index(dist.get_rank())
            output = torch.narrow(tensor, dim, start, length).contiguous()
            return output
 def _all_to_all(tensor: torch.Tensor, comm_spec: CommSpec):
    '''
    Implement all to all operation on device mesh based on information provided by comm_spec.
    '''
    process_groups_list = comm_spec.process_groups_dict[comm_spec.logical_process_axis]
    for rank_list, process_group in process_groups_list:
        if dist.get_rank() in rank_list:
            new_shape = list(tensor.shape)
            new_shape[comm_spec.shard_dim] = new_shape[comm_spec.shard_dim] // len(rank_list)
            new_shape = torch.Size(new_shape)
            output_tensor_list = [
                torch.zeros(new_shape, dtype=tensor.dtype, device=tensor.device) for _ in range(len(rank_list))
            ]
            dim = comm_spec.shard_dim
            length = tensor.shape[comm_spec.shard_dim] // len(rank_list)
            input_tensor_list = [
                torch.narrow(tensor, dim, length * i, length).contiguous() for i in range(len(rank_list))
            ]
            group = process_group
            dist.all_to_all(output_tensor_list, input_tensor_list, group)
            output = torch.cat(tuple(output_tensor_list), comm_spec.gather_dim).contiguous()
            return output
 def _all_reduce(tensor: torch.Tensor, comm_spec: CommSpec, async_op: bool = False):
    '''
    Implement all reduce operation on device mesh based on information provided by comm_spec.
    '''
    process_groups_list = comm_spec.process_groups_dict[comm_spec.logical_process_axis]
    for rank_list, process_group in process_groups_list:
        if dist.get_rank() in rank_list:
            if not tensor.is_contiguous():
                tensor = tensor.contiguous()
            dist.all_reduce(tensor, op=ReduceOp.SUM, group=process_group, async_op=async_op)
            return tensor
 class _ReduceGrad(torch.autograd.Function):
    """
    A customized communication operation which forward is an identity operation,
    backward is all_reduce operation.
    Args:
        input_: input matrix.
        comm_spec: comm_spec will give information like process group, rank list, etc.
    """
    @staticmethod
    def symbolic(graph, input_):
        return input_
    @staticmethod
    def forward(ctx, input_, comm_spec):
        ctx.comm_spec = comm_spec
        return input_
    @staticmethod
    def backward(ctx, grad_output):
        return _all_reduce(grad_output, ctx.comm_spec), None
 class _ReduceInput(torch.autograd.Function):
    """
    A customized communication operation which forward is all_reduce operation,
    backward is an identity operation.
    Args:
        input_: input matrix.
        comm_spec: comm_spec will give information like process group, rank list, etc.
    """
    @staticmethod
    def symbolic(graph, input_):
        return _all_reduce(input_)
    @staticmethod
    def forward(ctx, input_, comm_spec):
        return _all_reduce(input_, comm_spec)
    @staticmethod
    def backward(ctx, grad_output):
        return grad_output, None
 class _SplitForwardGatherBackward(torch.autograd.Function):
    """
    A customized communication operation which forward is split operation,
    backward is an all gather operation.
    Args:
        input_: input matrix.
        comm_spec: comm_spec will give information like process group, rank list, etc.
    """
    @staticmethod
    def symbolic(graph, input_):
        return _split(input_)
    @staticmethod
    def forward(ctx, input_, comm_spec):
        ctx.comm_spec = comm_spec
        return _split(input_, comm_spec)
    @staticmethod
    def backward(ctx, grad_output):
        return _all_gather(grad_output, ctx.comm_spec), None
 class _GatherForwardSplitBackward(torch.autograd.Function):
    """
    A customized communication operation which forward is an all gather operation,
    backward is split operation.
    Args:
        input_: input matrix.
        comm_spec: comm_spec will give information like process group, rank list, etc.
    """
    @staticmethod
    def symbolic(graph, input_):
        return _all_gather(input_)
    @staticmethod
    def forward(ctx, input_, comm_spec):
        ctx.comm_spec = comm_spec
        return _all_gather(input_, comm_spec)
    @staticmethod
    def backward(ctx, grad_output):
        return _split(grad_output, ctx.comm_spec), None
 class _AllToAll(torch.autograd.Function):
    """
    A customized communication operation which forward is an all to all operation,
    backward is an all to all operation.
    Args:
        input_: input matrix.
        comm_spec: comm_spec will give information like process group, rank list, etc.
    """
    @staticmethod
    def symbolic(graph, input_):
        return _all_to_all(input_)
    @staticmethod
    def forward(ctx, input_, comm_spec):
        output = _all_to_all(input_, comm_spec)
        comm_spec_for_backward = CommSpec(comm_pattern=comm_spec.comm_pattern,
                                          process_groups_dict=comm_spec.process_groups_dict,
                                          gather_dim=comm_spec.shard_dim,
                                          shard_dim=comm_spec.gather_dim,
                                          logical_process_axis=comm_spec.logical_process_axis)
        ctx.comm_spec = comm_spec_for_backward
        return output
    @staticmethod
    def backward(ctx, grad_outputs):
        return _all_to_all(grad_outputs, ctx.comm_spec), None
 def reduce_grad(input_, comm_spec):
    return _ReduceGrad.apply(input_, comm_spec)
 def reduce_input(input_, comm_spec):
    return _ReduceInput.apply(input_, comm_spec)
 def split_forward_gather_backward(input_, comm_spec):
    return _SplitForwardGatherBackward.apply(input_, comm_spec)
 def gather_forward_split_backward(input_, comm_spec):
    return _GatherForwardSplitBackward.apply(input_, comm_spec)
 def all_to_all(input_, comm_spec):
    return _AllToAll.apply(input_, comm_spec)
 pattern_to_func_dict = {
    CollectiveCommPattern.GATHER_FWD_SPLIT_BWD: gather_forward_split_backward,
    CollectiveCommPattern.ALL2ALL_FWD_ALL2ALL_BWD: all_to_all,
    CollectiveCommPattern.SPLIT_FWD_GATHER_BWD: split_forward_gather_backward,
    CollectiveCommPattern.ALLREDUCE_FWD_IDENTITY_BWD: reduce_input,
    CollectiveCommPattern.IDENTITY_FWD_ALLREDUCE_BWD: reduce_grad,
 }
--- a/colossalai/tensor/d_tensor/sharding_spec.py
+++ b/colossalai/tensor/d_tensor/sharding_spec.py
@ -171,7 +171,7 @@ class ShardingSpec:
            raise ShardingOutOfIndexError(
                f'sharding_sequence should have {self.dims} elements, but got index {len(self.sharding_sequence)}.')
-        if max(list(self.dim_partition_dict.keys())) >= self.dims:
+        if list(self.dim_partition_dict.keys()) and max(list(self.dim_partition_dict.keys())) >= self.dims:
            raise ShardingOutOfIndexError(
                f'the key of dim_partition_dict should be less than {self.dims}, but got {max(list(self.dim_partition_dict.keys()))}.'
            )
--- a/tests/test_tensor/test_dtensor/test_comm_spec.py
+++ b/tests/test_tensor/test_dtensor/test_comm_spec.py
@ -0,0 +1,190 @@
 from functools import partial
 import pytest
 import torch
 import torch.distributed as dist
 import torch.multiprocessing as mp
 from torch.distributed import ReduceOp
 from colossalai.core import global_context as gpc
 from colossalai.device.device_mesh import DeviceMesh
 from colossalai.initialize import launch
 from colossalai.logging import disable_existing_loggers
 from colossalai.tensor.d_tensor.comm_spec import CollectiveCommPattern, CommSpec
 from colossalai.tensor.d_tensor.sharding_spec import ShardingSpec
 from colossalai.testing import rerun_if_address_is_in_use
 from colossalai.utils import free_port
 def check_all_gather(process_groups_dict, rank):
    # tensor to comm
    if rank in (0, 2):
        sharded_tensor_to_comm = torch.ones(2, 2).cuda()
    else:
        sharded_tensor_to_comm = torch.zeros(2, 2).cuda()
    # tensor to check
    tensor_to_check = torch.cat((torch.ones(2, 2), torch.zeros(2, 2)), 1).cuda()
    # CommSpec:(comm_pattern:allgather, gather_dim:1, logical_process_axis:1)
    comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD,
                         process_groups_dict,
                         gather_dim=1,
                         logical_process_axis=1)
    sharded_tensor_to_comm = sharded_tensor_to_comm = comm_spec.covert_spec_to_action(sharded_tensor_to_comm)
    assert sharded_tensor_to_comm.equal(tensor_to_check)
 def check_shard(process_groups_dict, rank):
    # tensor to comm
    sharded_tensor_to_comm_0 = torch.zeros(2, 2).cuda()
    sharded_tensor_to_comm_1 = torch.ones(2, 2).cuda()
    # tensor([[0., 0., 1., 1.],
    #         [0., 0., 1., 1.]])
    tensor_to_shard = torch.cat((sharded_tensor_to_comm_0, sharded_tensor_to_comm_1), 1)
    # CommSpec:(comm_pattern:shard, shard_dim:1, logical_process_axis:1)
    comm_spec = CommSpec(CollectiveCommPattern.SPLIT_FWD_GATHER_BWD,
                         process_groups_dict,
                         shard_dim=1,
                         logical_process_axis=1)
    tensor_to_shard = comm_spec.covert_spec_to_action(tensor_to_shard)
    if rank in (0, 2):
        assert tensor_to_shard.equal(sharded_tensor_to_comm_0)
    if rank in (1, 3):
        assert tensor_to_shard.equal(sharded_tensor_to_comm_1)
 def check_all_to_all(process_groups_dict, rank):
    # tensor to comm
    if rank in (0, 1):
        sharded_tensor_0 = torch.zeros(2, 1)
        sharded_tensor_1 = torch.ones(2, 1)
        # tensor([[0., 1.],
        #         [0., 1.]])
        tensor_to_comm = torch.cat((sharded_tensor_0, sharded_tensor_1), 1).cuda()
    if rank in (2, 3):
        sharded_tensor_0 = torch.ones(2, 1) * 2
        sharded_tensor_1 = torch.ones(2, 1) * 3
        # tensor([[2., 3.],
        #         [2., 3.]])
        tensor_to_comm = torch.cat((sharded_tensor_0, sharded_tensor_1), 1).cuda()
    if rank in (0, 1):
        # tensor([[0.],
        #         [0.],
        #         [2.],
        #         [2.]])
        tensor_to_check = torch.tensor([[0], [0], [2], [2]], dtype=tensor_to_comm.dtype).cuda()
    if rank in (2, 3):
        # tensor([[1.],
        #         [1.],
        #         [3.],
        #         [3.]])
        tensor_to_check = torch.tensor([[1], [1], [3], [3]], dtype=tensor_to_comm.dtype).cuda()
    # CommSpec:(comm_pattern:shard, shard_dim:1, logical_process_axis:1)
    comm_spec = CommSpec(CollectiveCommPattern.ALL2ALL_FWD_ALL2ALL_BWD,
                         process_groups_dict,
                         gather_dim=0,
                         shard_dim=1,
                         logical_process_axis=0)
    tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm)
    assert tensor_to_comm.equal(tensor_to_check)
 def check_all_reduce_fwd(process_groups_dict, rank):
    # tensor to comm
    tensor_to_comm = torch.ones(2, 2).cuda() * rank
    # reduce through logical process axis 0
    # tensor to check
    if rank in (0, 2):
        # tensor([[2., 2.],
        #         [2., 2.]])
        tensor_to_check = torch.tensor([[2, 2], [2, 2]], dtype=tensor_to_comm.dtype).cuda()
    if rank in (1, 3):
        # tensor([[4., 4.],
        #         [4., 4.]])
        tensor_to_check = torch.tensor([[4, 4], [4, 4]], dtype=tensor_to_comm.dtype).cuda()
    comm_spec = CommSpec(CollectiveCommPattern.ALLREDUCE_FWD_IDENTITY_BWD, process_groups_dict, logical_process_axis=0)
    tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm)
    assert tensor_to_comm.equal(tensor_to_check)
 def check_all_reduce_bwd(process_groups_dict, rank):
    # tensor to comm
    tensor_to_comm = torch.ones(2, 2).cuda() * rank
    tensor_to_check = torch.ones(2, 2).cuda() * rank
    comm_spec = CommSpec(CollectiveCommPattern.IDENTITY_FWD_ALLREDUCE_BWD, process_groups_dict, logical_process_axis=0)
    tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm)
    assert tensor_to_comm.equal(tensor_to_check)
 def check_all_reduce_in_flatten_device_mesh(process_groups_dict, rank):
    # tensor to comm
    tensor_to_comm = torch.ones(2, 2).cuda() * rank
    # reduce through logical process axis 0 at flatten device mesh
    # tensor to check
    # tensor([[6., 6.],
    #         [6., 6.]])
    tensor_to_check = torch.tensor([[6, 6], [6, 6]], dtype=tensor_to_comm.dtype).cuda()
    # CommSpec:(comm_pattern:all_reduce, logical_process_axis:[0, 1])
    comm_spec = CommSpec(CollectiveCommPattern.ALLREDUCE_FWD_IDENTITY_BWD, process_groups_dict, logical_process_axis=0)
    tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm)
    assert tensor_to_comm.equal(tensor_to_check)
 def check_comm(rank, world_size, port):
    disable_existing_loggers()
    launch(config={}, rank=rank, world_size=world_size, host='localhost', port=port, backend='nccl')
    physical_mesh_id = torch.arange(0, 4)
    assert rank == gpc.get_global_rank()
    mesh_shape = (2, 2)
    # [[0, 1,
    #  [2, 3]]
    device_mesh = DeviceMesh(physical_mesh_id, mesh_shape, init_process_group=True)
    process_groups_dict = device_mesh.process_groups_dict
    # test all gather
    check_all_gather(process_groups_dict, rank)
    # test shard
    check_shard(process_groups_dict, rank)
    # test all to all
    check_all_to_all(process_groups_dict, rank)
    # test all reduce
    check_all_reduce_fwd(process_groups_dict, rank)
    check_all_reduce_bwd(process_groups_dict, rank)
    flatten_process_groups_dict = device_mesh.flatten_device_mesh.process_groups_dict
    # test all reduce in 1D flatten device mesh
    check_all_reduce_in_flatten_device_mesh(flatten_process_groups_dict, rank)
    gpc.destroy()
@pytest.mark.dist
@rerun_if_address_is_in_use()
 def test_comm_spec():
    world_size = 4
    run_func = partial(check_comm, world_size=world_size, port=free_port())
    mp.spawn(run_func, nprocs=world_size)
 if __name__ == '__main__':
    test_comm_spec()