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2026-07-13 12:40:42 +08:00

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Python

# Copyright (c) 2023 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import os
import numpy as np
import paddle
import paddle.distributed as dist
from paddle import nn
from paddle.distributed import Partial, Replicate, Shard
class TestReshardAPI:
def __init__(self):
self._shape = eval(os.getenv("shape"))
self._dtype = os.getenv("dtype")
self._seeds = eval(os.getenv("seeds"))
self._backend = os.getenv("backend")
self._shard = eval(os.getenv("shard"))
self._mesh = dist.ProcessMesh([0, 1], dim_names=["x"])
def run_test_cases(self):
if self._backend == "cpu":
paddle.set_device("cpu")
self.test_case_p_to_r()
self.test_case_r_to_s()
self.test_case_forward_and_backward()
self.test_case_p_to_s_reshard_grad()
self.test_case_p_to_r_reshard_grad()
def test_case_p_to_r(self):
a = paddle.ones(self._shape)
in_shard_specs = [None for i in range(len(self._shape))]
out_shard_specs = [None for i in range(len(self._shape))]
input_tensor = dist.shard_tensor(a, self._mesh, [Partial()])
output_tensor = dist.reshard(input_tensor, self._mesh, [Replicate()])
input_tensor = dist.shard_tensor(a, self._mesh, [Replicate()])
assert np.equal(output_tensor.shape, input_tensor.shape).all()
np.testing.assert_equal(output_tensor._local_value().numpy(), a.numpy())
def test_case_r_to_s(self):
a = paddle.ones(self._shape)
input_tensor = dist.shard_tensor(a, self._mesh, [Replicate()])
output_tensor = dist.reshard(input_tensor, self._mesh, [Shard(0)])
out_shape = list(self._shape)
if out_shape[self._shard] % 2 == 0:
out_shape[self._shard] = out_shape[self._shard] // 2
np.testing.assert_equal(output_tensor.numpy(), input_tensor.numpy())
else:
out_shape[self._shard] = (
out_shape[self._shard] // 2
if dist.get_rank() == 1
else out_shape[self._shard] // 2 + 1
)
assert np.equal(output_tensor.shape, input_tensor.shape).all()
assert np.equal(output_tensor._local_shape, out_shape).all()
def test_case_forward_and_backward(self):
if self._backend == "cpu":
return
np.random.seed(1901)
input_numpy = np.random.random(self._shape).astype("float32")
label_numpy = np.random.random(self._shape).astype('float32')
local_input = paddle.to_tensor(input_numpy)
dist_input = dist.shard_tensor(
paddle.to_tensor(input_numpy),
dist.ProcessMesh([0, 1], dim_names=["x"]),
[Replicate()],
)
local_input.stop_gradient = False
dist_input.stop_gradient = False
local_output = local_input + paddle.ones(self._shape)
dist_output = dist_input + dist.shard_tensor(
paddle.ones(self._shape),
dist.ProcessMesh([0, 1], dim_names=["x"]),
[Replicate()],
)
dist_output.stop_gradient = False
dist_output = dist.reshard(
dist_output, dist.ProcessMesh([0, 1], dim_names=["x"]), [Shard(0)]
)
local_label = paddle.to_tensor(label_numpy)
dist_label = dist.shard_tensor(
paddle.to_tensor(label_numpy),
dist.ProcessMesh([0, 1], dim_names=["x"]),
[Shard(0)],
)
local_loss_fn = nn.MSELoss()
dist_loss_fn = nn.MSELoss()
local_loss = local_loss_fn(local_output, local_label)
dist_loss = dist_loss_fn(dist_output, dist_label)
np.testing.assert_allclose(
local_loss.numpy(), dist_loss.numpy(), rtol=1e-5, atol=1e-5
)
local_loss.backward()
dist_loss.backward()
np.testing.assert_allclose(
local_input.grad.numpy(),
dist_input.grad.numpy(),
rtol=1e-5,
atol=1e-5,
)
def test_case_p_to_s_reshard_grad(self):
if self._backend == "cpu":
return
np.random.seed(1901)
input_numpy = np.random.random(self._shape).astype("float32")
label_numpy = np.random.random(self._shape).astype('float32')
dist_input = dist.shard_tensor(
paddle.to_tensor(input_numpy),
dist.ProcessMesh([0, 1], dim_names=["x"]),
[Partial()],
)
dist_input.stop_gradient = False
dist_output = dist.reshard(
dist_input, dist.ProcessMesh([0, 1], dim_names=["x"]), [Shard(0)]
)
dist_label = dist.shard_tensor(
paddle.to_tensor(label_numpy),
dist.ProcessMesh([0, 1], dim_names=["x"]),
[Shard(0)],
)
dist_loss_fn = nn.MSELoss()
dist_loss = dist_loss_fn(dist_output, dist_label)
dist_loss.backward()
np.testing.assert_equal(dist_input.grad.placements, [dist.Replicate()])
def test_case_p_to_r_reshard_grad(self):
if self._backend == "cpu":
return
np.random.seed(1901)
input_numpy = np.random.random(self._shape).astype("float32")
label_numpy = np.random.random(self._shape).astype('float32')
dist_input = dist.shard_tensor(
paddle.to_tensor(input_numpy),
dist.ProcessMesh([0, 1], dim_names=["x"]),
[Partial()],
)
dist_input.stop_gradient = False
dist_output = dist.reshard(
dist_input, dist.ProcessMesh([0, 1], dim_names=["x"]), [Replicate()]
)
dist_label = dist.shard_tensor(
paddle.to_tensor(label_numpy),
dist.ProcessMesh([0, 1], dim_names=["x"]),
[Replicate()],
)
dist_loss_fn = nn.MSELoss()
dist_loss = dist_loss_fn(dist_output, dist_label)
dist_loss.backward()
np.testing.assert_equal(dist_input.grad.placements, [dist.Replicate()])
if __name__ == '__main__':
TestReshardAPI().run_test_cases()