[dy2stat] Set shape for linspace to Fix dy2stat for GridGenerator Model (#29173)

GridGenerator model failed because the output shape of `linspace` is (-1). The reason is that C++ InferShape fixes the shape to (-1): https://github.com/PaddlePaddle/Paddle/blob/5da3d514ebaa6fffd48c4a2e6bb5b16268dae92e/paddle/fluid/operators/linspace_op.cc#L49 We cannot set the shape in C++ infer shape because this Tensor may not be initialized during compile time, but when input `num` of `linspace` is an integer, we know the shape at compiler time. This PR simply set the shape in Python and add GridGenerator as unittest.

[dy2stat] Set shape for linspace to Fix dy2stat for GridGenerator Model (#29173)
GridGenerator model failed because the output shape of `linspace` is (-1). The reason is that C++ InferShape fixes the shape to (-1): https://github.com/PaddlePaddle/Paddle/blob/5da3d514ebaa6fffd48c4a2e6bb5b16268dae92e/paddle/fluid/operators/linspace_op.cc#L49 We cannot set the shape in C++ infer shape because this Tensor may not be initialized during compile time, but when input `num` of `linspace` is an integer, we know the shape at compiler time. This PR simply set the shape in Python and add GridGenerator as unittest.
4a0a8701 · Huihuang Zheng · GitHub · cb680c80 · 4a0a8701 · 4a0a8701
2 changed file
--- a/python/paddle/fluid/layers/tensor.py
+++ b/python/paddle/fluid/layers/tensor.py
@@ -1477,6 +1477,8 @@ def linspace(start, stop, num, dtype=None, name=None):
                'Num': tensor_num},
        attrs={'dtype': dtype},
        outputs={'Out': [out]})
+    if isinstance(num, int):
+        out.desc.set_shape((num, ))
    return out



--- a/python/paddle/fluid/tests/unittests/dygraph_to_static/test_grid_generator.py
+++ b/python/paddle/fluid/tests/unittests/dygraph_to_static/test_grid_generator.py
+# copyright (c) 2020 PaddlePaddle Authors. All Rights Reserve.
+#
+# 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.
+
+from __future__ import absolute_import
+from __future__ import division
+from __future__ import print_function
+
+import paddle
+from paddle import nn, ParamAttr
+
+import numpy as np
+import unittest
+
+np.random.seed(2020)
+paddle.seed(2020)
+
+
+class GridGenerator(nn.Layer):
+    def __init__(self, in_channels, num_fiducial):
+        super(GridGenerator, self).__init__()
+        self.eps = 1e-6
+        self.F = num_fiducial
+
+        initializer = nn.initializer.Constant(value=0.0)
+        param_attr = ParamAttr(learning_rate=0.0, initializer=initializer)
+        bias_attr = ParamAttr(learning_rate=0.0, initializer=initializer)
+        self.fc = nn.Linear(
+            in_channels, 6, weight_attr=param_attr, bias_attr=bias_attr)
+
+    @paddle.jit.to_static(input_spec=[
+        paddle.static.InputSpec(
+            shape=[None, 3, 32, 100], dtype='float32'), paddle.static.InputSpec(
+                shape=[32, 100], dtype='float32')
+    ])
+    def forward(self, batch_C_prime, I_r_size):
+        """
+        Generate the grid for the grid_sampler.
+        Args:
+            batch_C_prime: the matrix of the geometric transformation
+            I_r_size: the shape of the input image
+        Return:
+            batch_P_prime: the grid for the grid_sampler
+        """
+        C = self.build_C_paddle()
+        return C
+
+    def build_C_paddle(self):
+        """ Return coordinates of fiducial points in I_r; C """
+        F = self.F
+        ctrl_pts_x = paddle.linspace(-1.0, 1.0, int(F / 2))
+        ctrl_pts_y_top = -1 * paddle.ones([int(F / 2)])
+        ctrl_pts_y_bottom = paddle.ones([int(F / 2)])
+        ctrl_pts_top = paddle.stack([ctrl_pts_x, ctrl_pts_y_top], axis=1)
+        ctrl_pts_bottom = paddle.stack([ctrl_pts_x, ctrl_pts_y_bottom], axis=1)
+        C = paddle.concat([ctrl_pts_top, ctrl_pts_bottom], axis=0)
+        return C
+
+    def build_P_paddle(self, I_r_size):
+        I_r_width, I_r_height = I_r_size
+        I_r_grid_x = paddle.divide(
+            (paddle.arange(-I_r_width, I_r_width, 2).astype('float32') + 1.0),
+            paddle.to_tensor(I_r_width).astype('float32'))
+        I_r_grid_y = paddle.divide(
+            (paddle.arange(-I_r_height, I_r_height, 2).astype('float32') + 1.0),
+            paddle.to_tensor(I_r_height).astype('float32'))
+        P = paddle.stack(paddle.meshgrid(I_r_grid_x, I_r_grid_y), axis=2)
+        P = paddle.transpose(P, perm=[1, 0, 2])
+        return P.reshape([-1, 2])
+
+    def build_inv_delta_C_paddle(self, C):
+        """ Return inv_delta_C which is needed to calculate T """
+        F = self.F
+        hat_C = paddle.zeros((F, F), dtype='float32')
+        for i in range(0, F):
+            for j in range(i, F):
+                if i == j:
+                    hat_C[i, j] = 1
+                else:
+                    r = paddle.norm(C[i] - C[j])
+                    hat_C[i, j] = r
+                    hat_C[j, i] = r
+        hat_C = (hat_C**2) * paddle.log(hat_C)
+        delta_C = paddle.concat(
+            [
+                paddle.concat(
+                    [paddle.ones((F, 1)), C, hat_C], axis=1),
+                paddle.concat(
+                    [paddle.zeros((2, 3)), paddle.transpose(
+                        C, perm=[1, 0])],
+                    axis=1), paddle.concat(
+                        [paddle.zeros((1, 3)), paddle.ones((1, F))], axis=1)
+            ],
+            axis=0)
+        inv_delta_C = paddle.inverse(delta_C)
+        return inv_delta_C
+
+    def build_P_hat_paddle(self, C, P):
+        F = self.F
+        eps = self.eps
+        n = P.shape[0]
+        P_tile = paddle.tile(paddle.unsqueeze(P, axis=1), (1, F, 1))
+        C_tile = paddle.unsqueeze(C, axis=0)
+        P_diff = P_tile - C_tile
+        rbf_norm = paddle.norm(P_diff, p=2, axis=2, keepdim=False)
+
+        rbf = paddle.multiply(
+            paddle.square(rbf_norm), paddle.log(rbf_norm + eps))
+        P_hat = paddle.concat([paddle.ones((n, 1)), P, rbf], axis=1)
+        return P_hat
+
+    def get_expand_tensor(self, batch_C_prime):
+        B, H, C = batch_C_prime.shape
+        batch_C_prime = batch_C_prime.reshape([B, H * C])
+        batch_C_ex_part_tensor = self.fc(batch_C_prime)
+        batch_C_ex_part_tensor = batch_C_ex_part_tensor.reshape([-1, 3, 2])
+        return batch_C_ex_part_tensor
+
+
+class TestGridGenerator(unittest.TestCase):
+    def setUp(self):
+        self.x = paddle.uniform(shape=[1, 20, 2], dtype='float32')
+
+    def _run(self, to_static):
+        prog_trans = paddle.jit.ProgramTranslator()
+        prog_trans.enable(to_static)
+
+        net = GridGenerator(40, 20)
+        ret = net(self.x, [32, 100])
+        return ret.numpy()
+
+    def test_to_static(self):
+        st_out = self._run(to_static=True)
+        dy_out = self._run(to_static=False)
+        np.testing.assert_allclose(st_out, dy_out)
+
+
+if __name__ == '__main__':
+    unittest.main()