mirror of https://github.com/hpcaitech/ColossalAI
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333 lines
12 KiB
333 lines
12 KiB
from functools import partial |
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import pytest |
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import torch |
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import torch.multiprocessing as mp |
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from colossalai.core import global_context as gpc |
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from colossalai.device.device_mesh import DeviceMesh |
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from colossalai.initialize import launch |
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from colossalai.logging import disable_existing_loggers |
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from colossalai.tensor.shape_consistency import CollectiveCommPattern, CommSpec |
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from colossalai.tensor.sharding_spec import ShardingSpec |
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from colossalai.tensor.utils import mix_gather_simulator |
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from colossalai.utils import free_port |
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def check_mix_gather_S0S1(device_mesh, rank): |
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tensor_to_check = torch.arange(64).reshape((8, 8)).cuda() |
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(f, b) = (0, 1) |
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f_target_pair = (f, [0]) |
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b_target_pair = (b, [1]) |
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gather_dim, logical_process_axes = mix_gather_simulator(f_target_pair, b_target_pair) |
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tensor_slice = [4, 2] # (4, 2) |
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rank_slice = 4 |
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f_start = (rank // rank_slice) * tensor_slice[0] |
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b_start = (rank % rank_slice) * tensor_slice[1] |
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tensor_to_comm = tensor_to_check[f_start:f_start + tensor_slice[0], |
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b_start:b_start + tensor_slice[1]].contiguous().cuda() |
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dim_partition_dict = {0: [0], 1: [1]} |
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# DistSpec: |
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# shard_sequence: S0,S1 |
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# device_mesh_shape: (2, 4) |
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source_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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comm_spec = CommSpec(CollectiveCommPattern.MIXGATHER_FWD_SPLIT_BWD, |
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sharding_spec=source_spec, |
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gather_dim=gather_dim, |
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logical_process_axis=logical_process_axes, |
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forward_only=True, |
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mix_gather=True) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_two_all_gather_S0S1(device_mesh, rank): |
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tensor_width = 8 |
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tensor_to_check = torch.arange(int(tensor_width * tensor_width)).reshape((tensor_width, tensor_width)).cuda() |
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dim_partition_dict = {0: [0], 1: [1]} |
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tensor_slice = [tensor_width // 2, tensor_width // 4] # (4, 2) |
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rank_slice = 4 |
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f_start = (rank // rank_slice) * tensor_slice[0] |
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b_start = (rank % rank_slice) * tensor_slice[1] |
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tensor_to_comm = tensor_to_check[f_start:f_start + tensor_slice[0], |
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b_start:b_start + tensor_slice[1]].contiguous().cuda() |
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# DistSpec: |
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# shard_sequence: S0,S1 |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:0, logical_process_axis:0) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=0, |
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logical_process_axis=0) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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dim_partition_dict = {1: [1]} |
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# DistSpec: |
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# shard_sequence: R,S1 |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:1, logical_process_axis:1) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=1, |
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logical_process_axis=1) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_mix_gather_S1S0(device_mesh, rank): |
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tensor_to_check = torch.arange(64).reshape((8, 8)).cuda() |
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(f, b) = (0, 1) |
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f_target_pair = (f, [1]) |
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b_target_pair = (b, [0]) |
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gather_dim, logical_process_axes = mix_gather_simulator(f_target_pair, b_target_pair) |
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tensor_slice = [2, 4] |
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rank_slice = 4 |
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f_start = (rank % rank_slice) * tensor_slice[0] |
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b_start = (rank // rank_slice) * tensor_slice[1] |
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tensor_to_comm = tensor_to_check[f_start:f_start + tensor_slice[0], |
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b_start:b_start + tensor_slice[1]].contiguous().cuda() |
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dim_partition_dict = {0: [1], 1: [0]} |
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# DistSpec: |
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# shard_sequence: S1,S0 |
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# device_mesh_shape: (2, 4) |
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source_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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comm_spec = CommSpec(CollectiveCommPattern.MIXGATHER_FWD_SPLIT_BWD, |
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sharding_spec=source_spec, |
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gather_dim=gather_dim, |
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logical_process_axis=logical_process_axes, |
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forward_only=True, |
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mix_gather=True) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_two_all_gather_S1S0(device_mesh, rank): |
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tensor_width = 8 |
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tensor_to_check = torch.arange(int(tensor_width * tensor_width)).reshape((tensor_width, tensor_width)).cuda() |
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tensor_slice = [tensor_width // 4, tensor_width // 2] # (4, 2) |
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rank_slice = 4 |
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f_start = (rank % rank_slice) * tensor_slice[0] |
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b_start = (rank // rank_slice) * tensor_slice[1] |
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tensor_to_comm = tensor_to_check[f_start:f_start + tensor_slice[0], |
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b_start:b_start + tensor_slice[1]].contiguous().cuda() |
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dim_partition_dict = {0: [1], 1: [0]} |
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# DistSpec: |
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# shard_sequence: S1,S0 |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:0, logical_process_axis:1) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=0, |
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logical_process_axis=1) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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dim_partition_dict = {1: [0]} |
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# DistSpec: |
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# shard_sequence: R,S0 |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:1, logical_process_axis:0) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=1, |
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logical_process_axis=0) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_mix_gather_S01R(device_mesh, rank): |
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tensor_to_check = torch.arange(64).reshape((8, 8)).cuda() |
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(f, b) = (0, 1) |
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f_target_pair = (f, [0, 1]) |
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b_target_pair = (b, []) |
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gather_dim, logical_process_axes = mix_gather_simulator(f_target_pair, b_target_pair) |
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tensor_to_comm = tensor_to_check[rank:rank + 1, :].contiguous().cuda() |
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dim_partition_dict = {0: [0, 1]} |
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# DistSpec: |
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# shard_sequence: S01,R |
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# device_mesh_shape: (2, 4) |
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source_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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comm_spec = CommSpec(CollectiveCommPattern.MIXGATHER_FWD_SPLIT_BWD, |
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sharding_spec=source_spec, |
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gather_dim=gather_dim, |
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logical_process_axis=logical_process_axes, |
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forward_only=True, |
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mix_gather=True) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_two_all_gather_S01R(device_mesh, rank): |
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tensor_width = 8 |
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tensor_to_check = torch.arange(int(tensor_width * tensor_width)).reshape((tensor_width, tensor_width)).cuda() |
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rank_stride = tensor_width // 8 |
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tensor_to_comm = tensor_to_check[rank:rank + rank_stride, :].contiguous().cuda() |
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dim_partition_dict = {0: [0, 1]} |
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# DistSpec: |
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# shard_sequence: S01, R |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:0, logical_process_axis:0) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=0, |
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logical_process_axis=1) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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dim_partition_dict = {0: [0]} |
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# DistSpec: |
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# shard_sequence: S1, R |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:0, logical_process_axis:1) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=0, |
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logical_process_axis=0) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_mix_gather_RS01(device_mesh, rank): |
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tensor_to_check = torch.arange(64).reshape((8, 8)).cuda() |
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(f, b) = (0, 1) |
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f_target_pair = (f, []) |
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b_target_pair = (b, [0, 1]) |
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gather_dim, logical_process_axes = mix_gather_simulator(f_target_pair, b_target_pair) |
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tensor_to_comm = tensor_to_check[:, rank:rank + 1].contiguous().cuda() |
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dim_partition_dict = {1: [0, 1]} |
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# DistSpec: |
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# shard_sequence: R, S01 |
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# device_mesh_shape: (2, 4) |
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source_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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comm_spec = CommSpec(CollectiveCommPattern.MIXGATHER_FWD_SPLIT_BWD, |
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sharding_spec=source_spec, |
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gather_dim=gather_dim, |
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logical_process_axis=logical_process_axes, |
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forward_only=True, |
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mix_gather=True) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_two_all_gather_RS01(device_mesh, rank): |
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tensor_width = 8 |
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tensor_to_check = torch.arange(int(tensor_width * tensor_width)).reshape((tensor_width, tensor_width)).cuda() |
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rank_stride = tensor_width // 8 |
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tensor_to_comm = tensor_to_check[:, rank:rank + rank_stride].contiguous().cuda() |
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dim_partition_dict = {1: [0, 1]} |
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# DistSpec: |
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# shard_sequence: R, S01 |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:1, logical_process_axis:0) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=1, |
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logical_process_axis=1) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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dim_partition_dict = {1: [0]} |
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# DistSpec: |
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# shard_sequence: R, S1 |
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# device_mesh_shape: (2, 4) |
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sharding_spec = ShardingSpec(device_mesh, tensor_to_check.shape, dim_partition_dict=dim_partition_dict) |
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# CommSpec:(comm_pattern:allgather, gather_dim:1, logical_process_axis:1) |
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comm_spec = CommSpec(CollectiveCommPattern.GATHER_FWD_SPLIT_BWD, |
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sharding_spec, |
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gather_dim=1, |
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logical_process_axis=0) |
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tensor_to_comm = comm_spec.covert_spec_to_action(tensor_to_comm) |
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assert tensor_to_comm.equal(tensor_to_check) |
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def check_comm(rank, world_size, port): |
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disable_existing_loggers() |
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launch(config={}, rank=rank, world_size=world_size, host='localhost', port=port, backend='nccl') |
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physical_mesh_id = torch.arange(0, 8) |
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assert rank == gpc.get_global_rank() |
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mesh_shape = (2, 4) |
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# [[0, 1, 2, 3], |
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# [4, 5, 6, 7]] |
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device_mesh = DeviceMesh(physical_mesh_id, mesh_shape, init_process_group=True, need_flatten=True) |
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check_mix_gather_S0S1(device_mesh, rank) |
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check_two_all_gather_S0S1(device_mesh, rank) |
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check_mix_gather_S1S0(device_mesh, rank) |
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check_two_all_gather_S1S0(device_mesh, rank) |
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check_mix_gather_S01R(device_mesh, rank) |
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check_two_all_gather_S01R(device_mesh, rank) |
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check_mix_gather_RS01(device_mesh, rank) |
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check_two_all_gather_RS01(device_mesh, rank) |
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@pytest.mark.skip(reason="Skip because the check functions assume 8 GPUS but CI only have 4 GPUs") |
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def test_mix_gather(): |
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world_size = 8 |
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run_func = partial(check_comm, world_size=world_size, port=free_port()) |
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mp.spawn(run_func, nprocs=world_size) |
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if __name__ == '__main__': |
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test_mix_gather()
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