test_sparse_elementwise_op.py 7.8 KB
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# Copyright (c) 2022 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 unittest
from operator import __add__, __sub__, __mul__, __truediv__

import numpy as np
import paddle
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import paddle.sparse as sparse
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op_list = [__add__, __sub__, __mul__, __truediv__]


def get_actual_res(x, y, op):
    if op == __add__:
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        res = paddle.sparse.add(x, y)
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    elif op == __sub__:
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        res = paddle.sparse.subtract(x, y)
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    elif op == __mul__:
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        res = paddle.sparse.multiply(x, y)
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    elif op == __truediv__:
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        res = paddle.sparse.divide(x, y)
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    else:
        raise ValueError("unsupported op")
    return res


class TestSparseElementWiseAPI(unittest.TestCase):
    """
    test paddle.sparse.add, subtract, multiply, divide
    """

    def setUp(self):
        paddle.fluid.set_flags({"FLAGS_retain_grad_for_all_tensor": True})
        np.random.seed(2022)
        self.op_list = op_list
        self.csr_shape = [128, 256]
        self.coo_shape = [4, 8, 3, 5]
        self.support_dtypes = ['float32', 'float64', 'int32', 'int64']

    def func_test_csr(self, op):
        for dtype in self.support_dtypes:
            x = np.random.randint(-255, 255, size=self.csr_shape).astype(dtype)
            y = np.random.randint(-255, 255, size=self.csr_shape).astype(dtype)

            dense_x = paddle.to_tensor(x, dtype=dtype, stop_gradient=False)
            dense_y = paddle.to_tensor(y, dtype=dtype, stop_gradient=False)

            s_dense_x = paddle.to_tensor(x, dtype=dtype, stop_gradient=False)
            s_dense_y = paddle.to_tensor(y, dtype=dtype, stop_gradient=False)
            csr_x = s_dense_x.to_sparse_csr()
            csr_y = s_dense_y.to_sparse_csr()

            actual_res = get_actual_res(csr_x, csr_y, op)
            actual_res.backward(actual_res)

            expect_res = op(dense_x, dense_y)
            expect_res.backward(expect_res)

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            np.testing.assert_allclose(expect_res.numpy(),
                                       actual_res.to_dense().numpy(),
                                       rtol=1e-05,
                                       equal_nan=True)
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            if not (op == __truediv__ and dtype in ['int32', 'int64']):
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                np.testing.assert_allclose(dense_x.grad.numpy(),
                                           csr_x.grad.to_dense().numpy(),
                                           rtol=1e-05,
                                           equal_nan=True)
                np.testing.assert_allclose(dense_y.grad.numpy(),
                                           csr_y.grad.to_dense().numpy(),
                                           rtol=1e-05,
                                           equal_nan=True)
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    def func_test_coo(self, op):
        for sparse_dim in range(len(self.coo_shape) - 1, len(self.coo_shape)):
            for dtype in self.support_dtypes:
                x = np.random.randint(-255, 255,
                                      size=self.coo_shape).astype(dtype)
                y = np.random.randint(-255, 255,
                                      size=self.coo_shape).astype(dtype)

                dense_x = paddle.to_tensor(x, dtype=dtype, stop_gradient=False)
                dense_y = paddle.to_tensor(y, dtype=dtype, stop_gradient=False)

                s_dense_x = paddle.to_tensor(x,
                                             dtype=dtype,
                                             stop_gradient=False)
                s_dense_y = paddle.to_tensor(y,
                                             dtype=dtype,
                                             stop_gradient=False)
                coo_x = s_dense_x.to_sparse_coo(sparse_dim)
                coo_y = s_dense_y.to_sparse_coo(sparse_dim)

                actual_res = get_actual_res(coo_x, coo_y, op)
                actual_res.backward(actual_res)

                expect_res = op(dense_x, dense_y)
                expect_res.backward(expect_res)

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                np.testing.assert_allclose(expect_res.numpy(),
                                           actual_res.to_dense().numpy(),
                                           rtol=1e-05,
                                           equal_nan=True)
                np.testing.assert_allclose(dense_x.grad.numpy(),
                                           coo_x.grad.to_dense().numpy(),
                                           rtol=1e-05,
                                           equal_nan=True)
                np.testing.assert_allclose(dense_y.grad.numpy(),
                                           coo_y.grad.to_dense().numpy(),
                                           rtol=1e-05,
                                           equal_nan=True)
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    def test_support_dtypes_csr(self):
        paddle.device.set_device('cpu')
        if paddle.device.get_device() == "cpu":
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            for op in op_list:
                self.func_test_csr(op)
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    def test_support_dtypes_coo(self):
        paddle.device.set_device('cpu')
        if paddle.device.get_device() == "cpu":
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            for op in op_list:
                self.func_test_coo(op)
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    def test_add_same_indices(self):
        indices_data = [[0, 1], [0, 3]]
        values1_data = [[1.0], [2.0]]
        values2_data = [[1.0], [2.0]]
        shape = [2, 4, 2]

        sp_a = sparse.sparse_coo_tensor(indices_data,
                                        values1_data,
                                        shape,
                                        stop_gradient=False)
        sp_b = sparse.sparse_coo_tensor(indices_data,
                                        values2_data,
                                        shape,
                                        stop_gradient=False)

        values1 = paddle.to_tensor(values1_data, stop_gradient=False)
        values2 = paddle.to_tensor(values2_data, stop_gradient=False)

        #c.values() = a.values() + b.values()
        sp_c = sparse.add(sp_a, sp_b)
        sp_c.backward()
        ref_c = values1 + values2
        ref_c.backward()
        np.testing.assert_allclose(sp_c.values().numpy(), ref_c.numpy())
        np.testing.assert_allclose(sp_a.grad.values().numpy(),
                                   values1.grad.numpy())
        np.testing.assert_allclose(sp_b.grad.values().numpy(),
                                   values2.grad.numpy())

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    def test_add_bias(self):
        indices_data = [[0, 1], [0, 3]]
        values_data = [[1.0, 1.0], [2.0, 2.0]]
        shape = [2, 4, 2]

        sp_a = sparse.sparse_coo_tensor(indices_data,
                                        values_data,
                                        shape,
                                        stop_gradient=False)

        bias_values = [1.0, 2.0]

        values1 = paddle.to_tensor(values_data, stop_gradient=False)
        values2 = paddle.to_tensor(bias_values, stop_gradient=False)
        values3 = paddle.to_tensor(bias_values, stop_gradient=False)

        #c.values() = a.values() + b
        sp_c = sparse.add(sp_a, values2)
        sp_c.backward()
        ref_c = values1 + values3
        ref_c.backward()
        np.testing.assert_allclose(sp_c.values().numpy(), ref_c.numpy())
        np.testing.assert_allclose(sp_a.grad.values().numpy(),
                                   values1.grad.numpy())
        np.testing.assert_allclose(values2.grad.numpy(), values3.grad.numpy())

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if __name__ == "__main__":
    paddle.device.set_device('cpu')
    unittest.main()