327 lines
12 KiB
Python
327 lines
12 KiB
Python
# Copyright (c) 2024 PaddlePaddle Authors. All Rights Reserved.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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import os
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import unittest
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import numpy as np
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import paddle
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import paddle.distributed as dist
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from paddle.distributed.auto_parallel.moe_utils import (
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_only_reshard_mesh_shape,
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get_local_slices,
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get_rank2tensor_indices,
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shard_submesh_and_slice,
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)
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class TestMoEUtils(unittest.TestCase):
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def __init__(self):
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self._dtype = os.getenv("dtype")
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self._seeds = eval(os.getenv("seeds"))
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self._backend = os.getenv("backend")
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self._mesh0 = dist.ProcessMesh([[0], [1]], dim_names=["x", "y"]) # 2x1
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self._mesh1 = dist.ProcessMesh([[0, 1]], dim_names=["x", "y"]) # 1x2
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self._mesh2 = dist.ProcessMesh(
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[0, 1], dim_names=["x"]
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) # 1D mesh with 2 processes
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paddle.seed(self._seeds)
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# Ensure the environment flag is set for _only_reshard_mesh_shape
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os.environ["FLAGS_enable_moe_utils"] = "true"
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# Existing tests (unchanged)
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def test_local_reshape(self):
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(h, w) = (4, 4)
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src_shape = [h, w]
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tgt_shape = [h // 2, w * 2]
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x = paddle.arange(0, h * w).reshape(src_shape)
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x.stop_gradient = False
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np_x = x.numpy()
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dist_x = dist.shard_tensor(
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x, self._mesh0, [dist.Shard(1), dist.Replicate()]
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)
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dist_y = dist.auto_parallel.moe_utils._dist_reshape(
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dist_x, [-1, w * 2], self._mesh0, [dist.Shard(1), dist.Replicate()]
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)
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splitted_np_x = np.split(np_x, 2, axis=1)
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for i in range(len(splitted_np_x)):
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splitted_np_x[i] = splitted_np_x[i].reshape([h // 2, w])
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np.testing.assert_array_equal(
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splitted_np_x[dist.get_rank()], dist_y._local_value().numpy()
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)
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label = paddle.ones(tgt_shape, dtype=paddle.int64)
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label.stop_gradient = False
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dist_label = dist.shard_tensor(
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label, self._mesh0, [dist.Shard(1), dist.Replicate()]
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)
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loss = dist_y - dist_label
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loss.backward()
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np_grad = np.ones(src_shape, dtype="int64")
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splitted_np_grad = np.split(np_grad, 2, axis=1)
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np.testing.assert_array_equal(
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splitted_np_grad[dist.get_rank()],
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dist_x.grad._local_value().numpy(),
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)
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# with np.testing.assert_raises(AssertionError):
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# dist_z = dist.auto_parallel.moe_utils._dist_reshape(
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# dist_x,
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# dist_x.shape,
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# self._mesh1,
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# [dist.Replicate(), dist.Replicate()],
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# )
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dist_z = dist.auto_parallel.moe_utils._dist_reshape(
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dist_x, dist_x.shape, self._mesh0, [dist.Shard(1), dist.Shard(1)]
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)
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# python -m paddle.distributed.launch --devices=0,1 semi_auto_parallel_moe_utils.py
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def test_nd_mesh_alltoall(self):
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if self._backend == "cpu":
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return
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(h, w) = (4, 4)
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src_shape = [h, w]
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x = paddle.arange(0, h * w).reshape(src_shape)
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x.stop_gradient = False
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dist_x = dist.shard_tensor(
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x, self._mesh0, [dist.Shard(1), dist.Replicate()]
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)
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dist_y = dist.reshard(
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dist_x, self._mesh0, [dist.Shard(0), dist.Replicate()]
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)
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dist_y.backward()
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np.testing.assert_equal(
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dist_y.placements, [dist.Shard(0), dist.Replicate()]
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)
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np.testing.assert_equal(
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dist_x.grad.placements, [dist.Shard(1), dist.Replicate()]
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)
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np_grad = np.ones(src_shape, dtype="int64")
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splitted_np_grad = np.split(np_grad, 2, axis=1)
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np.testing.assert_array_equal(
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splitted_np_grad[dist.get_rank()],
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dist_x.grad._local_value().numpy(),
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)
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def test_reshard_mesh_shape(self):
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(h, w) = (4, 4)
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src_shape = [h, w]
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x = paddle.arange(0, h * w).reshape(src_shape)
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dist_x = dist.shard_tensor(
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x, self._mesh0, [dist.Replicate(), dist.Replicate()]
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)
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dist_y = dist.reshard(
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dist_x, self._mesh1, [dist.Replicate(), dist.Replicate()]
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)
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np.testing.assert_equal(dist_y.process_mesh, self._mesh1)
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np.testing.assert_array_equal(
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dist_y._local_value().numpy(), dist_x._local_value().numpy()
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)
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def test_get_local_slices(self):
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(h, w) = (4, 4)
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src_shape = [h, w]
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x = paddle.arange(0, h * w).reshape(src_shape)
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placements = [dist.Shard(0), dist.Partial()]
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dist_x = dist.shard_tensor(x, self._mesh0, placements)
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dist_x_local_slices = get_local_slices(x, self._mesh0, placements)
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np.testing.assert_equal(
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dist_x_local_slices[0]['slice'], [(0, 2), (0, 4)]
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)
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np.testing.assert_equal(
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dist_x_local_slices[0]['partial'][1],
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dist_x.placements[1].reduce_type(),
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)
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np.testing.assert_equal(
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dist_x_local_slices[1]['slice'], [(2, 4), (0, 4)]
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)
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np.testing.assert_equal(
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dist_x_local_slices[1]['partial'][1],
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dist_x.placements[1].reduce_type(),
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)
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y = paddle.arange(0, h * w).reshape(src_shape)
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y_placements = [dist.Shard(0)]
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dist_y = dist.shard_tensor(y, self._mesh0, y_placements)
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dist_y_local_slices = get_local_slices(
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dist_y, self._mesh0, y_placements
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)
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np.testing.assert_equal(
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dist_y_local_slices[0]['slice'], [(0, 2), (0, 4)]
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)
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np.testing.assert_equal(
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dist_y_local_slices[1]['slice'], [(2, 4), (0, 4)]
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)
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# with self.assertRaises(ValueError):
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# tmp_placements = [dist.Shard(0), dist.Shard(1), dist.Replicate()]
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# dist_y_local_slices = get_local_slices(
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# dist_y, self._mesh0, tmp_placements
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# )
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# python -m paddle.distributed.launch --devices=0,1 semi_auto_parallel_moe_utils.py
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def test_reshard_general_case(self):
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"""Test reshard when _only_reshard_mesh_shape returns False."""
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(h, w) = (4, 4)
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x = paddle.arange(0, h * w, dtype=self._dtype).reshape([h, w])
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dist_x = dist.shard_tensor(x, self._mesh2, [dist.Replicate()])
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dist_y = dist.reshard(dist_x, self._mesh2, [dist.Shard(0)])
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if dist.get_rank() == 0:
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expected_y = x[:2, :] # Process 0 gets first half of axis 0
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np.testing.assert_array_equal(
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dist_y._local_value().numpy(), expected_y.numpy()
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)
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elif dist.get_rank() == 1:
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expected_y = x[2:, :] # Process 1 gets second half of axis 0
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np.testing.assert_array_equal(
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dist_y._local_value().numpy(), expected_y.numpy()
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)
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def test_shard_submesh_and_slice(self):
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"""Test shard_submesh_and_slice with even and uneven tensor sizes."""
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mesh = dist.ProcessMesh([[0, 1]], dim_names=["x", "y"]) # 1x2 mesh
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tensor_slice = [(0, 4), (0, 4)]
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tensor_dim = 0
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mesh_dim = 1
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new_sub_meshes, new_slices = shard_submesh_and_slice(
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mesh, tensor_slice, tensor_dim, mesh_dim
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)
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np.testing.assert_equal(len(new_sub_meshes), 2)
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np.testing.assert_equal(new_sub_meshes[0].process_ids, [0])
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np.testing.assert_equal(new_sub_meshes[1].process_ids, [1])
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np.testing.assert_equal(new_slices[0], [(0, 2), (0, 4)])
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np.testing.assert_equal(new_slices[1], [(2, 4), (0, 4)])
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# Uneven size
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tensor_slice = [(0, 5), (0, 4)]
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new_sub_meshes, new_slices = shard_submesh_and_slice(
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mesh, tensor_slice, tensor_dim, mesh_dim
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)
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np.testing.assert_equal(
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new_slices[0], [(0, 3), (0, 4)]
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) # First shard: 3 elements
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np.testing.assert_equal(
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new_slices[1], [(3, 5), (0, 4)]
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) # Last shard: 2 elements
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def test_get_rank2tensor_indices(self):
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"""Test get_rank2tensor_indices mapping."""
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sub_mesh_indices_info = {
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dist.ProcessMesh([0]): [(0, 2), (0, 4)],
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dist.ProcessMesh([1]): [(2, 4), (0, 4)],
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}
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sub_mesh_partial_info = {}
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rank2tensor_indices = get_rank2tensor_indices(
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sub_mesh_indices_info, sub_mesh_partial_info
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)
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np.testing.assert_equal(
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rank2tensor_indices[0], {'slice': [(0, 2), (0, 4)], 'partial': {}}
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)
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np.testing.assert_equal(
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rank2tensor_indices[1], {'slice': [(2, 4), (0, 4)], 'partial': {}}
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)
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def test_get_local_slices_additional(self):
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"""Test get_local_slices with different placements."""
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(h, w) = (4, 4)
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x = paddle.arange(0, h * w, dtype=self._dtype).reshape([h, w])
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# Test with [Replicate(), Replicate()]
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placements = [dist.Replicate(), dist.Replicate()]
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slices = get_local_slices(x, self._mesh0, placements)
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for rank in [0, 1]:
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np.testing.assert_equal(slices[rank]['slice'], [(0, 4), (0, 4)])
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np.testing.assert_equal(slices[rank]['partial'], {})
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# Test with [Shard(1), Replicate()] on mesh1
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placements = [dist.Replicate(), dist.Shard(1)]
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slices = get_local_slices(x, self._mesh1, placements)
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np.testing.assert_equal(slices[0]['slice'], [(0, 4), (0, 2)])
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np.testing.assert_equal(slices[1]['slice'], [(0, 4), (2, 4)])
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def test_only_reshard_mesh_shape(self):
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"""Test _only_reshard_mesh_shape conditions."""
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(h, w) = (4, 4)
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x = paddle.arange(0, h * w, dtype=self._dtype).reshape([h, w])
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# Case 1: Same mesh, should return False
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dist_x = dist.shard_tensor(
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x, self._mesh0, [dist.Replicate(), dist.Replicate()]
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)
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result = _only_reshard_mesh_shape(
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dist_x, self._mesh0, [dist.Replicate(), dist.Replicate()]
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)
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assert not result
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# Case 2: Different process IDs, should return False
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mesh_diff = dist.ProcessMesh([[2], [3]], dim_names=["x", "y"])
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result = _only_reshard_mesh_shape(
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dist_x, mesh_diff, [dist.Replicate(), dist.Replicate()]
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)
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assert not result
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# Case 3: Same process IDs, different slices
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dist_x = dist.shard_tensor(
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x, self._mesh0, [dist.Shard(0), dist.Replicate()]
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)
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result = _only_reshard_mesh_shape(
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dist_x, self._mesh1, [dist.Replicate(), dist.Shard(1)]
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)
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assert not result
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# Case 4: Same process IDs, same slices
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dist_x = dist.shard_tensor(
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x, self._mesh0, [dist.Replicate(), dist.Replicate()]
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)
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result = _only_reshard_mesh_shape(
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dist_x, self._mesh1, [dist.Replicate(), dist.Replicate()]
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)
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assert result
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# Case 5: Flag disabled
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os.environ["FLAGS_enable_moe_utils"] = "false"
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result = _only_reshard_mesh_shape(
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dist_x, self._mesh1, [dist.Replicate(), dist.Replicate()]
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)
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assert not result
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os.environ["FLAGS_enable_moe_utils"] = "true" # Reset
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def run_test_case(self):
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if self._backend == "cpu":
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paddle.set_device("cpu")
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self.test_local_reshape()
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self.test_nd_mesh_alltoall()
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self.test_reshard_mesh_shape()
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self.test_get_local_slices()
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self.test_reshard_general_case()
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self.test_shard_submesh_and_slice()
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self.test_get_rank2tensor_indices()
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self.test_get_local_slices_additional()
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self.test_only_reshard_mesh_shape()
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if __name__ == '__main__':
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TestMoEUtils().run_test_case()
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