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mindspore/tests/ut/python/ops/test_ops.py

test_ops.py 57 kB
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initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
clean pylint
5 years ago
develop op ScatterMax and dock ge process
5 years ago
clean pylint
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
Add pack and unpack
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
Add pack and unpack
5 years ago
Fixing some tiny faults about Pylint in my code(ops)
5 years ago
Add pack and unpack
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
Add pack and unpack
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
Add pack and unpack
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
use reshape as flatten grad
5 years ago
add vm for cosh and sinh
5 years ago
use reshape as flatten grad
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Fixing some tiny faults about Pylint in my code(ops)
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Fixing some tiny faults about Pylint in my code(ops)
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Fixing some tiny faults about Pylint in my code(ops)
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add Histogram summary operator clean clang format errors and cpplint errors add some test cases for histogram summary operator
5 years ago
develop op ScatterMax and dock ge process
5 years ago
add Histogram summary operator clean clang format errors and cpplint errors add some test cases for histogram summary operator
5 years ago
develop op ScatterMax and dock ge process
5 years ago
clean pylint
5 years ago
add op scatter add vm
5 years ago
adapt Softplus\SoftplusGrad\ApplyFtrlD for VM
5 years ago
add tbe op SparseApplyProximalAdagradD-SparseApplyFtrlD-ApplyProximalAdagradD for VM
5 years ago
add applyrmsprop op for vm
5 years ago
Fixing some tiny faults about Pylint in my code(ops)
5 years ago
add applyrmsprop op for vm
5 years ago
develop op ScatterMax and dock ge process
5 years ago
add vm for cosh and sinh
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add op BitwiseAnd BitwiseOr BitwiseXor
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Support pow's second input could be tensor and fix bug in bprop of pow
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Support pow's second input could be tensor and fix bug in bprop of pow
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add vm support for Expm1
5 years ago
Add Erf\FillD operator for VM
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Register forward and backward operations of Ceil
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
为算子进行VM流程对接
5 years ago
Add FloorMod, Acosh in ME
5 years ago
为算子进行VM流程对接
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add vm ops: asin asinh asingrad asinhgrad
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Add FloorMod, Acosh in ME
5 years ago
fix bug of brpop of FloorMod
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
fix reviewboot and example of TruncatedNormal and add type mapping
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
NotEqual op auto cast Signed-off-by: candanzg <zhangshucheng@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
NotEqual op auto cast Signed-off-by: candanzg <zhangshucheng@huawei.com>
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add vm support sin and cumsum
5 years ago
Fixing some tiny faults about Pylint in my code(ops)
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add atan2 operator
5 years ago
add squaresumall op
5 years ago
add vm support sin and cumsum
5 years ago
add vms for reducealld etc.
5 years ago
vm for BesselI0e and BesselI1e
5 years ago
add register for Atan AtanGrad Atanh
5 years ago
add vm for cosh and sinh
5 years ago
add inv,invgrad&invert for vm
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Add ReluV2/ReluGradV2/ConfusionMulGrad for VM
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
adapt Softplus\SoftplusGrad\ApplyFtrlD for VM
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Develop op MaxPoolWithArgMax
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
use reshape as flatten grad
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
为L2Normalize/L2NormalizeGrad增加VM支持
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
modify ResizeNearestNeighborV2D
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add op BasicLSTMCell vm
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Add RangeD for GE
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
UnsortedSegmentMin for GE
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
modify api and add example
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
modify api and add example
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add tbe op SparseApplyProximalAdagradD-SparseApplyFtrlD-ApplyProximalAdagradD for VM
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
use reshape as flatten grad
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
adapt Softplus\SoftplusGrad\ApplyFtrlD for VM
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add RMSProp optimizer
5 years ago
add applyrmsprop op for vm
5 years ago
add RMSProp optimizer
5 years ago
为算子进行VM流程对接
5 years ago
add RMSProp optimizer
5 years ago
add ops CTCLoss
5 years ago
Add L2Loss op for VM
5 years ago
add ops for VM
5 years ago
Add L2Loss op for VM
5 years ago
接入算子resizebilinear and resizebilineargrad
5 years ago
add register info for ROIAlign and ROIAlignGrad
5 years ago
clean pylint
5 years ago
add register info for ROIAlign and ROIAlignGrad
5 years ago
add op BoundingBoxDecode iou NMSWithMask larsupdate testcase sgd testcase
5 years ago
clean pylint
5 years ago
add op BoundingBoxDecode iou NMSWithMask larsupdate testcase sgd testcase
5 years ago
add vms for binarycrossentropy and binarycrossentropygrad
5 years ago
add vms for reducealld etc.
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add vm for cosh and sinh
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add pack and unpack
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add pack and unpack
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add pack and unpack
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add pack and unpack
5 years ago
modified api name Stack -> Pack, Unstack -> Unpack
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add pack and unpack
5 years ago
delete pack description about num and add raise error SparseApplyAdagrad example format PReLU and grad state 1-d not supported atan2 bprop dx dy revert to original shapes
5 years ago
add operator diag and diag_part
5 years ago
delete pack description about num and add raise error SparseApplyAdagrad example format PReLU and grad state 1-d not supported atan2 bprop dx dy revert to original shapes
5 years ago
add operator diag and diag_part
5 years ago
delete pack description about num and add raise error SparseApplyAdagrad example format PReLU and grad state 1-d not supported atan2 bprop dx dy revert to original shapes
5 years ago
add operator SpaceToBatch and BatchToSpace for ge
5 years ago
validate bprop rules
5 years ago
add operator SpaceToBatch and BatchToSpace for ge
5 years ago
add vms for reducealld etc.
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
validate bprop rules
5 years ago
develop op ScatterMax and dock ge process
5 years ago
add op scatter add vm
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
Add ReluV2/ReluGradV2/ConfusionMulGrad for VM
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add ReluV2/ReluGradV2/ConfusionMulGrad for VM
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add ReluV2/ReluGradV2/ConfusionMulGrad for VM
5 years ago
develop op ScatterMax and dock ge process
5 years ago
Add ReluV2/ReluGradV2/ConfusionMulGrad for VM
5 years ago
add Histogram summary operator clean clang format errors and cpplint errors add some test cases for histogram summary operator
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
add vm for cosh and sinh
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
develop op ScatterMax and dock ge process
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
bugfix* fix bug in output tuple of tuple.* check kRWWrite input no-variable* input x of ScatterNdUpdate should be a parameter node
5 years ago
support tensor get value by tensor index support tensor set value by tensor index
5 years ago
bugfix* fix bug in output tuple of tuple.* check kRWWrite input no-variable* input x of ScatterNdUpdate should be a parameter node
5 years ago
delete pack description about num and add raise error SparseApplyAdagrad example format PReLU and grad state 1-d not supported atan2 bprop dx dy revert to original shapes
5 years ago
develop op ScatterMax and dock ge process
5 years ago
delete pack description about num and add raise error SparseApplyAdagrad example format PReLU and grad state 1-d not supported atan2 bprop dx dy revert to original shapes
5 years ago
develop op ScatterMax and dock ge process
5 years ago
delete pack description about num and add raise error SparseApplyAdagrad example format PReLU and grad state 1-d not supported atan2 bprop dx dy revert to original shapes
5 years ago
initial version Signed-off-by: leonwanghui <leon.wanghui@huawei.com>
5 years ago
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
  1. # Copyright 2020 Huawei Technologies Co., Ltd

  2. #

  3. # Licensed under the Apache License, Version 2.0 (the "License");

  4. # you may not use this file except in compliance with the License.

  5. # You may obtain a copy of the License at

  6. #

  7. # http://www.apache.org/licenses/LICENSE-2.0

  8. #

  9. # Unless required by applicable law or agreed to in writing, software

  10. # distributed under the License is distributed on an "AS IS" BASIS,

  11. # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.

  12. # See the License for the specific language governing permissions and

  13. # limitations under the License.

  14. # ============================================================================

  15. """ test ops """

  16. import functools

  17. import numpy as np

  18. 

  19. import mindspore.nn as nn

  20. import mindspore.ops.composite as C

  21. from mindspore import Tensor

  22. from mindspore import ops, Parameter, context

  23. from mindspore.common import dtype as mstype

  24. from mindspore.ops import functional as F

  25. from mindspore.ops import operations as P

  26. from mindspore.ops.operations import _grad_ops as G

  27. from ..ut_filter import non_graph_engine

  28. from ....mindspore_test_framework.mindspore_test import mindspore_test

  29. from ....mindspore_test_framework.pipeline.forward.compile_forward \

  30.     import (pipeline_for_compile_forward_ge_graph_for_case_by_case_config,

  31.             pipeline_for_compile_forward_ge_graph_for_case_by_case_config_exception)

  32. from ....mindspore_test_framework.pipeline.gradient.compile_gradient \

  33.     import pipeline_for_compile_grad_ge_graph_for_case_by_case_config

  34. 

  35. 

  36. class InputBackward(nn.Cell):

  37.     def __init__(self, network):

  38.         super(InputBackward, self).__init__()

  39.         self.network = network

  40.         self.network.set_train()

  41.         self.grad = C.grad_all_with_sens

  42. 

  43.     def construct(self, x1, x2, x3, sens):

  44.         return self.grad(self.network)(x1, x2, x3, sens)

  45. 

  46. 

  47. class NetForTupleInput(nn.Cell):

  48.     def __init__(self, op):

  49.         super(NetForTupleInput, self).__init__()

  50.         self.op = op

  51. 

  52.     def construct(self, x1, x2):

  53.         return self.op((x1, x2))

  54. 

  55. 

  56. class StridedSlicessdNet(nn.Cell):

  57.     def __init__(self):

  58.         super(StridedSlicessdNet, self).__init__()

  59.         self.rank = P.Rank()

  60. 

  61.     def construct(self, x1):

  62.         return P.StridedSlice(1, 1, 0, self.rank(x1), 0)(x1, (0, 0), (0, 0), (1, 1))

  63. 

  64. 

  65. class NetForConcat(nn.Cell):

  66.     def __init__(self):

  67.         super(NetForConcat, self).__init__()

  68.         self.concat = P.Concat()

  69. 

  70.     def construct(self, x1):

  71.         return self.concat((x1, x1))

  72. 

  73. 

  74. class NetForConcat1(nn.Cell):

  75.     def __init__(self):

  76.         super(NetForConcat1, self).__init__()

  77.         self.concat = P.Concat()

  78. 

  79.     def construct(self, x1, x2):

  80.         return self.concat((x1, x2))

  81. 

  82. 

  83. class NetForPackInput(nn.Cell):

  84.     def __init__(self, op):

  85.         super(NetForPackInput, self).__init__()

  86.         self.op = op

  87.         self.mul = P.Mul()

  88. 

  89.     def construct(self, *args):

  90.         t = ()

  91.         for element in args:

  92.             t = t + (self.mul(element, element),)

  93.         return self.op(t)

  94. 

  95. 

  96. class NetForUnpackInput(nn.Cell):

  97.     def __init__(self, op):

  98.         super(NetForUnpackInput, self).__init__()

  99.         self.op = op

  100.         self.mul = P.Mul()

  101. 

  102.     def construct(self, x1):

  103.         return self.op((self.mul(x1, x1)))

  104. 

  105. 

  106. class NetForFlatten(nn.Cell):

  107.     def __init__(self):

  108.         super(NetForFlatten, self).__init__()

  109.         self.flatten = P.Flatten()

  110. 

  111.     def construct(self, x, y):

  112.         return self.flatten(x) + y

  113. 

  114. 

  115. class NetForFlatten0D(nn.Cell):

  116.     def __init__(self):

  117.         super(NetForFlatten0D, self).__init__()

  118.         self.flatten = P.Flatten()

  119. 

  120.     def construct(self, x):

  121.         return self.flatten(x)

  122. 

  123. 

  124. class NetForFlattenComposed(nn.Cell):

  125.     # make flatten op together with other ops for testing flatten grad

  126.     def __init__(self):

  127.         super(NetForFlattenComposed, self).__init__()

  128.         self.flatten = P.Flatten()

  129. 

  130.     def construct(self, x, y):

  131.         return self.flatten(x + x) + y

  132. 

  133. 

  134. class ArgmaxNet(nn.Cell):

  135.     def __init__(self):

  136.         super(ArgmaxNet, self).__init__()

  137.         self.argmax = P.Argmax(axis=1)

  138. 

  139.     def construct(self, input_):

  140.         return self.argmax(input_)

  141. 

  142. 

  143. class ArgminNet(nn.Cell):

  144.     def __init__(self):

  145.         super(ArgminNet, self).__init__()

  146.         self.argmin = P.Argmin(axis=1)

  147. 

  148.     def construct(self, input_):

  149.         return self.argmin(input_)

  150. 

  151. 

  152. class CumSumNet(nn.Cell):

  153.     def __init__(self):

  154.         super(CumSumNet, self).__init__()

  155.         self.cumsum = P.CumSum()

  156.         self.axis = 1

  157. 

  158.     def construct(self, input_):

  159.         return self.cumsum(input_, self.axis)

  160. 

  161. 

  162. class SummaryNet(nn.Cell):

  163.     def __init__(self):

  164.         super(SummaryNet, self).__init__()

  165.         self.s = P.ScalarSummary()

  166.         self.add = P.TensorAdd()

  167. 

  168.     def construct(self, x, y):

  169.         self.s("x1", x)

  170.         return self.add(x, y)

  171. 

  172. 

  173. class HistogramSummaryNet(nn.Cell):

  174.     def __init__(self):

  175.         super(HistogramSummaryNet, self).__init__()

  176.         self.summary = P.HistogramSummary()

  177.         self.add = P.TensorAdd()

  178. 

  179.     def construct(self, x, y):

  180.         out = self.add(x, y)

  181.         string_in = "out"

  182.         self.summary(string_in, out)

  183.         return out

  184. 

  185. 

  186. class ScatterMax(nn.Cell):

  187.     """ScatterMax net definition"""

  188. 

  189.     def __init__(self):

  190.         super(ScatterMax, self).__init__()

  191.         self.scatter_max = P.ScatterMax()

  192.         self.ref = Parameter(Tensor(np.array([[1.0, 2.0, 3.0], [4.0, 5.0, 6.0]], np.float32)), name="ref")

  193. 

  194.     def construct(self, indices, updates):

  195.         out = self.scatter_max(self.ref, indices, updates)

  196.         return out

  197. 

  198. 

  199. class ScatterAdd(nn.Cell):

  200.     """ScatterAdd net definition"""

  201. 

  202.     def __init__(self, ref_shape):

  203.         super(ScatterAdd, self).__init__()

  204.         self.scatter_add = P.ScatterAdd()

  205.         self.ref = Parameter(Tensor(np.ones(ref_shape, np.float32)), name="ref")

  206. 

  207.     def construct(self, indices, updates):

  208.         out = self.scatter_add(self.ref, indices, updates)

  209.         return out

  210. 

  211. 

  212. class ApplyFtrlNet(nn.Cell):

  213.     def __init__(self):

  214.         super(ApplyFtrlNet, self).__init__()

  215.         self.apply_ftrl = P.ApplyFtrl()

  216.         self.lr = 0.001

  217.         self.l1 = 0.0

  218.         self.l2 = 0.0

  219.         self.lr_power = -0.5

  220.         self.var = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="var")

  221.         self.accum = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="accum")

  222.         self.linear = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="linear")

  223. 

  224.     def construct(self, grad):

  225.         out = self.apply_ftrl(self.var, self.accum, self.linear, grad, self.lr, self.l1, self.l2, self.lr_power)

  226.         return out

  227. 

  228. 

  229. class SparseApplyFtrlNet(nn.Cell):

  230.     def __init__(self):

  231.         super(SparseApplyFtrlNet, self).__init__()

  232.         self.sparse_apply_ftrl = P.SparseApplyFtrl(lr=0.001, l1=0.0, l2=0.0, lr_power=-0.5)

  233.         self.var = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="var")

  234.         self.accum = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="accum")

  235.         self.linear = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="linear")

  236. 

  237.     def construct(self, grad, indices):

  238.         out = self.sparse_apply_ftrl(self.var, self.accum, self.linear, grad, indices)

  239.         return out

  240. 

  241. 

  242. class SparseApplyProximalAdagradNet(nn.Cell):

  243.     def __init__(self):

  244.         super(SparseApplyProximalAdagradNet, self).__init__()

  245.         self.sparse_apply_proximal_adagrad = P.SparseApplyProximalAdagrad()

  246.         self.lr = 0.01

  247.         self.l1 = 0.0

  248.         self.l2 = 0.0

  249. 

  250.     def construct(self, var, accum, grad, indices):

  251.         out = self.sparse_apply_proximal_adagrad(var, accum, self.lr, self.l1, self.l2, grad, indices)

  252.         return out

  253. 

  254. 

  255. class ApplyProximalAdagradNet(nn.Cell):

  256.     def __init__(self):

  257.         super(ApplyProximalAdagradNet, self).__init__()

  258.         self.apply_proximal_adagrad = P.ApplyProximalAdagrad()

  259.         self.lr = 0.01

  260.         self.l1 = 0.0

  261.         self.l2 = 0.0

  262. 

  263.     def construct(self, var, accum, grad):

  264.         out = self.apply_proximal_adagrad(var, accum, self.lr, self.l1, self.l2, grad)

  265.         return out

  266. 

  267. 

  268. class ApplyRMSNet(nn.Cell):

  269.     def __init__(self):

  270.         super(ApplyRMSNet, self).__init__()

  271.         self.apply_rms = P.ApplyRMSProp()

  272.         self.lr = 0.001

  273.         self.rho = 0.0

  274.         self.momentum = 0.0

  275.         self.epsilon = 1e-10

  276.         self.var = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="var")

  277.         self.ms = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="ms")

  278.         self.moment = Parameter(Tensor(np.random.rand(3, 3).astype(np.float32)), name="moment")

  279. 

  280.     def construct(self, grad):

  281.         out = self.apply_rms(self.var, self.ms, self.moment, self.lr, grad, self.rho, self.momentum, self.epsilon)

  282.         return out

  283. 

  284. 

  285. test_case_math_ops = [

  286.     ('BitwiseAnd', {

  287.         'block': P.BitwiseAnd(),

  288.         'desc_inputs': [Tensor(np.array([0, 0, 1, -1, 1, 1, 1]), mstype.int16),

  289.                         Tensor(np.array([0, 1, 1, -1, -1, 2, 3]), mstype.int16)],

  290.         'skip': ['backward']}),

  291.     ('BitwiseAnd_1', {

  292.         'block': P.BitwiseAnd(),

  293.         'desc_inputs': [Tensor(np.array([[1, 2, 3], [-1, -2, -3]]), mstype.int16),

  294.                         Tensor(np.array([1, 1, 1]), mstype.int16)],

  295.         'skip': ['backward']}),

  296.     ('BitwiseOr', {

  297.         'block': P.BitwiseOr(),

  298.         'desc_inputs': [Tensor(np.array([0, 0, 1, -1, 1, 1, 1]), mstype.int16),

  299.                         Tensor(np.array([0, 1, 1, -1, -1, 2, 3]), mstype.int16)],

  300.         'skip': ['backward']}),

  301.     ('BitwiseOr_1', {

  302.         'block': P.BitwiseOr(),

  303.         'desc_inputs': [Tensor(np.array([[1, 2, 3], [-1, -2, -3]]), mstype.int16),

  304.                         Tensor(np.array([1, 1, 1]), mstype.int16)],

  305.         'skip': ['backward']}),

  306.     ('BitwiseXor', {

  307.         'block': P.BitwiseXor(),

  308.         'desc_inputs': [Tensor(np.array([0, 0, 1, -1, 1, 1, 1]), mstype.int16),

  309.                         Tensor(np.array([0, 1, 1, -1, -1, 2, 3]), mstype.int16)],

  310.         'skip': ['backward']}),

  311.     ('BitwiseXor_1', {

  312.         'block': P.BitwiseXor(),

  313.         'desc_inputs': [Tensor(np.array([[1, 2, 3], [-1, -2, -3]]), mstype.int16),

  314.                         Tensor(np.array([1, 1, 1]), mstype.int16)],

  315.         'skip': ['backward']}),

  316.     ('Neg', {

  317.         'block': P.Neg(),

  318.         'desc_inputs': [[1, 3, 4, 4]],

  319.         'desc_bprop': [[1, 3, 4, 4]]}),

  320.     ('Sub', {

  321.         'block': P.Sub(),

  322.         'desc_inputs': [[3, 5], [2, 3, 3, 5]],

  323.         'desc_bprop': [[2, 3, 3, 5]]}),

  324.     ('TensorAdd', {

  325.         'block': P.TensorAdd(),

  326.         'desc_inputs': [[3, 5], [2, 3, 3, 5]],

  327.         'desc_bprop': [[2, 3, 3, 5]]}),

  328.     ('Mul0', {

  329.         'block': P.Mul(),

  330.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 3, 5]],

  331.         'desc_bprop': [[2, 3, 3, 5]]}),

  332.     ('Mul1', {

  333.         'block': P.Mul(),

  334.         'desc_inputs': [[2, 3, 1, 1], [2, 3, 3, 5]],

  335.         'desc_bprop': [[2, 3, 3, 5]]}),

  336.     ('Mul2', {

  337.         'block': P.Mul(),

  338.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 1, 1]],

  339.         'desc_bprop': [[2, 3, 3, 5]],

  340.         'skip': ['backward']}),

  341.     ('Mul3', {

  342.         'block': P.Mul(),

  343.         'desc_inputs': [[3, 5], [2, 3, 3, 5]],

  344.         'desc_bprop': [[2, 3, 3, 5]],

  345.         'skip': ['backward']}),

  346.     ('Mul4', {

  347.         'block': P.Mul(),

  348.         'desc_inputs': [[2, 3, 3, 5], [3, 5]],

  349.         'desc_bprop': [[2, 3, 3, 5]],

  350.         'skip': ['backward']}),

  351.     ('Add0', {

  352.         'block': P.TensorAdd(),

  353.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 3, 5]],

  354.         'desc_bprop': [[2, 3, 3, 5]]}),

  355.     ('Add1', {

  356.         'block': P.TensorAdd(),

  357.         'desc_inputs': [[3, 5], [2, 3, 3, 5]],

  358.         'desc_bprop': [[2, 3, 3, 5]],

  359.         'skip': ['backward']}),

  360.     ('Add2', {

  361.         'block': P.TensorAdd(),

  362.         'desc_inputs': [[2, 3, 3, 5], [3, 5]],

  363.         'desc_bprop': [[2, 3, 3, 5]],

  364.         'skip': ['backward']}),

  365.     ('Add3', {

  366.         'block': P.TensorAdd(),

  367.         'desc_inputs': [[2, 3, 1, 1], [2, 3, 3, 5]],

  368.         'desc_bprop': [[2, 3, 3, 5]],

  369.         'skip': ['backward']}),

  370.     ('Add4', {

  371.         'block': P.TensorAdd(),

  372.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 1, 1]],

  373.         'desc_bprop': [[2, 3, 3, 5]],

  374.         'skip': ['backward']}),

  375.     ('Minimum', {

  376.         'block': P.Minimum(),

  377.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 3, 5]],

  378.         'desc_bprop': [[2, 3, 3, 5]]}),

  379.     ('Pow_0', {

  380.         'block': P.Pow(),

  381.         'desc_const': [2.0],

  382.         'desc_inputs': [[2, 3, 3, 5]],

  383.         'desc_bprop': [[2, 3, 3, 5]]}),

  384.     ('Pow_1', {

  385.         'block': P.Pow(),

  386.         'desc_inputs': [[3, 5], [2, 3, 3, 5]],

  387.         'desc_bprop': [[2, 3, 3, 5]]}),

  388.     ('Exp', {

  389.         'block': P.Exp(),

  390.         'desc_inputs': [[2, 3]],

  391.         'desc_bprop': [[2, 3]]}),

  392.     ('Expm1', {

  393.         'block': P.Expm1(),

  394.         'desc_inputs': [[2, 3]],

  395.         'desc_bprop': [[2, 3]]}),

  396.     ('Erf', {

  397.         'block': P.Erf(),

  398.         'desc_inputs': [Tensor(np.array([-2, -1, 0, 1, 2]).astype(np.float16))],

  399.         'desc_bprop': [Tensor(np.array([-2, -1, 0, 1, 2]).astype(np.float16))]}),

  400.     ('Floor', {

  401.         'block': P.Floor(),

  402.         'desc_inputs': [[2, 512, 56, 56]],

  403.         'desc_bprop': [[2, 512, 56, 56]],

  404.         'skip': ['backward']}),

  405.     ('Ceil', {

  406.         'block': P.Ceil(),

  407.         'desc_inputs': [[2, 512, 56, 56]],

  408.         'desc_bprop': [[2, 512, 56, 56]],

  409.         'skip': ['backward']}),

  410.     ('ACos', {

  411.         'block': P.ACos(),

  412.         'desc_inputs': [Tensor(np.array([2., 3.]).astype(np.float32))],

  413.         'desc_bprop': [Tensor(np.array([2., 3.]).astype(np.float32))]}),

  414.     ('ACosGrad', {

  415.         'block': G.ACosGrad(),

  416.         'desc_inputs': [[2, 3], [2, 3]],

  417.         'skip': ['backward']}),

  418.     ('Acosh', {

  419.         'block': P.Acosh(),

  420.         'desc_inputs': [Tensor(np.array([2., 3.]).astype(np.float32))],

  421.         'desc_bprop': [Tensor(np.array([2., 3.]).astype(np.float32))]}),

  422.     ('AcoshGrad', {

  423.         'block': G.AcoshGrad(),

  424.         'desc_inputs': [[2, 3], [2, 3]],

  425.         'skip': ['backward']}),

  426.     ('Sin', {

  427.         'block': P.Sin(),

  428.         'desc_inputs': [[2, 3]],

  429.         'desc_bprop': [[2, 3]]}),

  430.     ('Asin', {

  431.         'block': P.Asin(),

  432.         'desc_inputs': [[2, 3]],

  433.         'desc_bprop': [[2, 3]]}),

  434.     ('Asinh', {

  435.         'block': P.Asinh(),

  436.         'desc_inputs': [[3, 4, 5]],

  437.         'desc_bprop': [[3, 4, 5]]}),

  438.     ('Reciprocal', {

  439.         'block': P.Reciprocal(),

  440.         'desc_inputs': [[2, 3, 3, 5]],

  441.         'desc_bprop': [[2, 3, 3, 5]]}),

  442.     ('Minimum_0', {

  443.         'block': P.Minimum(),

  444.         'desc_inputs': [[2, 3, 3, 5], [3, 3, 5]],

  445.         'desc_bprop': [[2, 3, 3, 5]]}),

  446.     ('Maximum', {

  447.         'block': P.Maximum(),

  448.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 3, 5]],

  449.         'desc_bprop': [[2, 3, 3, 5]]}),

  450.     ('Maximum_0', {

  451.         'block': P.Maximum(),

  452.         'desc_inputs': [[3, 5], [2, 3, 3, 5]],

  453.         'desc_bprop': [[2, 3, 3, 5]]}),

  454.     ('MaximumGrad', {

  455.         'block': G.MaximumGrad(),

  456.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 3, 5], [2, 3, 3, 5]],

  457.         'skip': ['backward']}),

  458.     ('MinimumGrad', {

  459.         'block': G.MinimumGrad(),

  460.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 3, 5], [2, 3, 3, 5]],

  461.         'skip': ['backward']}),

  462.     ('StridedSlice', {

  463.         'block': P.StridedSlice(),

  464.         'desc_const': [(0, 1, 2, 1),

  465.                        (2, 3, 3, 4),

  466.                        (1, 1, 1, 1)],

  467.         'desc_inputs': [[2, 3, 3, 5]],

  468.         'desc_bprop': [[2, 2, 1, 3]]}),

  469.     ('Slice_1', {

  470.         'block': P.Slice(),

  471.         'desc_const': [(0, 1, 2, 1),

  472.                        (1, 1, 1, 2)],

  473.         'desc_inputs': [[2, 3, 3, 5]],

  474.         'desc_bprop': [[1, 1, 1, 2]]}),

  475.     ('StridedSliceGrad', {

  476.         'block': G.StridedSliceGrad(),

  477.         'desc_const': [(64, 1, 1024),

  478.                        (0, 1, 0),

  479.                        (64, 2, 1024),

  480.                        (1, 1, 1)],

  481.         'desc_inputs': [[64, 128, 1024]],

  482.         'skip': ['backward']}),

  483.     ('RandomChoiceWithMask', {

  484.         'block': P.RandomChoiceWithMask(256),

  485.         'desc_inputs': [Tensor(np.random.rand(24000, 4).astype(np.bool_))],

  486.         'desc_bprop': [[256, 4], [256, 4]],

  487.         'skip': ['backward']}),

  488.     ('LessEqual', {

  489.         'block': P.LessEqual(),

  490.         'desc_inputs': [Tensor(np.random.rand(4).astype(np.float16)),

  491.                         Tensor(np.random.rand(4).astype(np.float16))],

  492.         'skip': ['backward']}),

  493.     ('Less', {

  494.         'block': P.Less(),

  495.         'desc_inputs': [[2, 1, 4, 5], [2, 1, 4, 5]],

  496.         'desc_bprop': [Tensor(np.zeros((2, 1, 4, 5), np.bool_))],

  497.         'skip': ['backward']}),

  498.     ('RealDiv_0', {

  499.         'block': P.RealDiv(),

  500.         'desc_const': [Tensor(2048.0), Tensor(0.0)],

  501.         'desc_inputs': [],

  502.         'skip': ['backward']}),

  503.     ('RealDiv', {

  504.         'block': P.RealDiv(),

  505.         'desc_inputs': [[4], Tensor(np.ones(4).astype(np.float32))],

  506.         'desc_bprop': [[4]]}),

  507.     ('RealDiv_1', {

  508.         'block': P.RealDiv(),

  509.         'desc_inputs': [[512, 1024], [512, 1024]],

  510.         'desc_bprop': [[512, 1024]]}),

  511.     ('FloorDiv', {

  512.         'block': P.FloorDiv(),

  513.         'desc_inputs': [Tensor(np.random.rand(4).astype(np.float16)),

  514.                         Tensor(np.random.rand(4).astype(np.float16))],

  515.         'skip': ['backward']}),

  516.     ('FloorMod', {

  517.         'block': P.FloorMod(),

  518.         'desc_inputs': [[3, 4, 5], [2, 3, 4, 5]],

  519.         'desc_bprop': [[2, 3, 4, 5]]}),

  520.     ('identity', {

  521.         'block': ops.functional.identity,

  522.         'desc_inputs': [[2, 2]],

  523.         'skip': ['backward']}),

  524.     ('MatMul_1', {

  525.         'block': P.MatMul(transpose_a=False, transpose_b=False),

  526.         'desc_inputs': [[1024, 160], [160, 1024]],

  527.         'desc_bprop': [[1024, 1024]]}),

  528.     ('MatMul_2', {

  529.         'block': P.MatMul(transpose_a=True, transpose_b=True),

  530.         'desc_inputs': [[160, 1024], [1024, 160]],

  531.         'desc_bprop': [[1024, 1024]]}),

  532.     ('Sub', {

  533.         'block': P.Sub(),

  534.         'desc_inputs': [[3], [3]],

  535.         'desc_bprop': [[3]]}),

  536.     ('TruncatedNormal', {

  537.         'block': P.TruncatedNormal(),

  538.         'desc_const': [(1, 2, 3)],

  539.         'desc_inputs': [],

  540.         'skip': ['backward'],

  541.         'add_fake_input': True}),

  542.     ('Select', {

  543.         'block': P.Select(),

  544.         'desc_inputs': [Tensor(np.array([[True, False, False], [False, True, True]])),

  545.                         [2, 3], [2, 3]],

  546.         'desc_bprop': [[2, 3]]}),

  547.     ('Rank', {

  548.         'block': P.Rank(),

  549.         'desc_inputs': [[2, 3]],

  550.         'skip': ['backward']}),

  551.     ('InvertPermutation', {

  552.         'block': P.InvertPermutation(),

  553.         'desc_const': [(0, 3, 1, 2)],

  554.         'desc_inputs': [],

  555.         'skip': ['backward']}),

  556.     ('Square', {

  557.         'block': P.Square(),

  558.         'desc_inputs': [[4]],

  559.         'desc_bprop': [[4]]}),

  560.     ('Rsqrt', {

  561.         'block': P.Rsqrt(),

  562.         'desc_inputs': [[4]],

  563.         'desc_bprop': [[4]]}),

  564.     ('Sqrt', {

  565.         'block': P.Sqrt(),

  566.         'desc_inputs': [[4]],

  567.         'desc_bprop': [[4]]}),

  568.     ('RealDiv', {

  569.         'block': P.RealDiv(),

  570.         'desc_inputs': [[4, 5], [2, 3, 4, 5]],

  571.         'desc_bprop': [[2, 3, 4, 5]]}),

  572.     ('Div', {

  573.         'block': P.Div(),

  574.         'desc_inputs': [[4, 5], [2, 3, 4, 5]],

  575.         'desc_bprop': [[2, 3, 4, 5]]}),

  576.     ('Equal', {

  577.         'block': P.Equal(),

  578.         'desc_inputs': [[3, 4, 5], [4, 5]],

  579.         'desc_bprop': [Tensor(np.zeros((3, 4, 5), np.bool_))]}),

  580.     ('NotEqual', {

  581.         'block': P.NotEqual(),

  582.         'desc_inputs': [[4, 1], [2, 3, 4, 5]],

  583.         'desc_bprop': [Tensor(np.ones((2, 3, 4, 5), np.bool_))]}),

  584.     ('NotEqual_0', {

  585.         'block': P.NotEqual(),

  586.         'desc_inputs': [1, [2, 3, 4, 5]],

  587.         'desc_bprop': [Tensor(np.ones((2, 3, 4, 5), np.bool_))],

  588.         'skip': ['backward']}),

  589.     ('Greater', {

  590.         'block': P.Greater(),

  591.         'desc_inputs': [[2, 3, 4, 1], [4, 5]],

  592.         'desc_bprop': [Tensor(np.ones((2, 3, 4, 5), np.bool_))]}),

  593.     ('GreaterEqual', {

  594.         'block': P.GreaterEqual(),

  595.         'desc_inputs': [[2, 3, 4, 1], [4, 5]],

  596.         'desc_bprop': [Tensor(np.ones((2, 3, 4, 5), np.bool_))]}),

  597.     ('LogicalNot', {

  598.         'block': P.LogicalNot(),

  599.         'desc_inputs': [Tensor(np.zeros((3, 4, 5), np.bool_))],

  600.         'desc_bprop': [Tensor(np.ones((3, 4, 5), np.bool_))]}),

  601.     ('LogicalAnd', {

  602.         'block': P.LogicalAnd(),

  603.         'desc_inputs': [Tensor(np.zeros((2, 3, 4), np.bool_)), Tensor(np.ones((1), np.bool_))],

  604.         'desc_bprop': [Tensor(np.zeros((2, 3, 4), np.bool_))]}),

  605.     ('LogicalOr', {

  606.         'block': P.LogicalOr(),

  607.         'desc_inputs': [Tensor(np.zeros((3, 4, 5), np.bool_)), Tensor(np.ones((3, 1, 1), np.bool_))],

  608.         'desc_bprop': [Tensor(np.zeros((3, 4, 5), np.bool_))]}),

  609.     ('NpuAllocFloatStatus', {

  610.         'block': P.NPUAllocFloatStatus(),

  611.         'desc_inputs': [],

  612.         'add_fack_input': True,

  613.         'fack_input_type': np.float32,

  614.         'desc_bprop': [Tensor(np.zeros([8]).astype(np.float32))],

  615.         'skip': ['backward']}),

  616.     ('NpuGetFloatStatus', {

  617.         'block': P.NPUGetFloatStatus(),

  618.         'desc_inputs': [Tensor(np.zeros([8]).astype(np.float32))],

  619.         'desc_bprop': [Tensor(np.zeros([8]).astype(np.float32))],

  620.         'skip': ['backward']}),

  621.     ('NpuClearFloatStatus', {

  622.         'block': P.NPUClearFloatStatus(),

  623.         'desc_inputs': [Tensor(np.zeros([8]).astype(np.float32))],

  624.         'desc_bprop': [Tensor(np.zeros([8]).astype(np.float32))],

  625.         'skip': ['backward']}),

  626.     ('CheckValid', {

  627.         'block': P.CheckValid(),

  628.         'desc_inputs': [[20000, 4], [3]],

  629.         'desc_bprop': [[20000]],

  630.         'skip': ['backward']}),

  631.     ('NMSWithMask', {

  632.         'block': P.NMSWithMask(0.5),

  633.         'desc_inputs': [[128, 5]],

  634.         'desc_bprop': [[128, 5], [128], [128]],

  635.         'skip': ['backward']}),

  636.     ('Abs', {

  637.         'block': P.Abs(),

  638.         'desc_inputs': [[4]],

  639.         'desc_bprop': [[4]]}),

  640.     ('CumSum', {

  641.         'block': CumSumNet(),

  642.         'desc_inputs': [Tensor(np.array([[3, 4, 6, 10], [1, 6, 7, 9], [4, 3, 8, 7], [1, 3, 7, 9]]).astype(np.float32))],

  643.         'desc_bprop': [Tensor(np.array([[3, 4, 6, 10], [1, 6, 7, 9], [4, 3, 8, 7],

  644.                                         [1, 3, 7, 9]]).astype(np.float32))]}),

  645.     ('ReduceSum_3', {

  646.         'block': P.ReduceSum(),

  647.         'desc_const': [0],

  648.         'desc_inputs': [[3, 2]],

  649.         'desc_bprop': [[2]]}),

  650.     ('ReduceSum_4', {

  651.         'block': P.ReduceSum(keep_dims=True),

  652.         'desc_const': [0],

  653.         'desc_inputs': [[3, 2]],

  654.         'desc_bprop': [[1, 2]]}),

  655.     ('ReduceSum_5', {

  656.         'block': P.ReduceSum(keep_dims=True),

  657.         'desc_inputs': [[2, 3, 4]],

  658.         'desc_bprop': [[1, 1, 1]]}),

  659.     ('ReduceSum_6', {

  660.         'block': P.ReduceSum(),

  661.         'desc_inputs': [[2, 3, 4]],

  662.         'desc_bprop': [[1]]}),

  663.     ('Sum_0', {

  664.         'block': P.ReduceSum(),

  665.         'desc_const': [(1,)],

  666.         'desc_inputs': [[3, 2]],

  667.         'desc_bprop': [[3]]}),

  668.     ('Sum_1', {

  669.         'block': P.ReduceSum(keep_dims=True),

  670.         'desc_const': [(1,)],

  671.         'desc_inputs': [[3, 2]],

  672.         'desc_bprop': [[3, 1]]}),

  673.     ('Sum_2', {

  674.         'block': P.ReduceSum(),

  675.         'desc_const': [(0, 1)],

  676.         'desc_inputs': [[3, 2]],

  677.         'desc_bprop': [[1]]}),

  678.     ('Sum_3', {

  679.         'block': P.ReduceSum(),

  680.         'desc_const': [0],

  681.         'desc_inputs': [[3, 2]],

  682.         'desc_bprop': [[2]]}),

  683.     ('Sum_4', {

  684.         'block': P.ReduceSum(keep_dims=True),

  685.         'desc_const': [0],

  686.         'desc_inputs': [[3, 2]],

  687.         'desc_bprop': [[1, 2]]}),

  688.     ('Sum_5', {

  689.         'block': P.ReduceSum(keep_dims=True),

  690.         'desc_const': [()],

  691.         'desc_inputs': [[2, 3, 4]],

  692.         'desc_bprop': [[1, 1, 1]]}),

  693.     ('Sum_6', {

  694.         'block': P.ReduceSum(),

  695.         'desc_const': [()],

  696.         'desc_inputs': [[2, 3, 4]],

  697.         'desc_bprop': [[1]]}),

  698.     ('Sign', {

  699.         'block': P.Sign(),

  700.         'desc_inputs': [[3]],

  701.         'desc_bprop': [[3]]}),

  702.     ('Round', {

  703.         'block': P.Round(),

  704.         'desc_inputs': [[3]],

  705.         'desc_bprop': [[3]]}),

  706.     ('Atan2', {

  707.         'block': P.Atan2(),

  708.         'desc_inputs': [Tensor(np.array([0, 1]).astype(np.float32)),

  709.                         Tensor(np.array([1, 1]).astype(np.float32))],

  710.         'desc_bprop': [[2]]}),

  711.     ('SquareSumAll', {

  712.         'block': P.SquareSumAll(),

  713.         'desc_inputs': [Tensor(np.array([0, 1, 4, 5]).astype(np.float32)),

  714.                         Tensor(np.array([1, 1, 3, 7]).astype(np.float32))],

  715.         'skip': ['backward']}),

  716.     ('Cos', {

  717.         'block': P.Cos(),

  718.         'desc_inputs': [[2, 3]],

  719.         'desc_bprop': [[2, 3]]}),

  720.     ('ReduceAll', {

  721.         'block': P.ReduceAll(),

  722.         'desc_const': [1],

  723.         'desc_inputs': [Tensor(np.array([[True, False], [True, True]]))],

  724.         'desc_bprop': []}),

  725.     ('BesselI0e', {

  726.         'block': P.BesselI0e(),

  727.         'desc_inputs': [[2, 3]],

  728.         'desc_bprop': [[2, 3]]}),

  729.     ('BesselI1e', {

  730.         'block': P.BesselI1e(),

  731.         'desc_inputs': [[2, 3]],

  732.         'desc_bprop': [[2, 3]]}),

  733.     ('Atan', {

  734.         'block': P.Atan(),

  735.         'desc_inputs': [[2, 3]],

  736.         'desc_bprop': [[2, 3]]}),

  737.     ('AtanGrad', {

  738.         'block': G.AtanGrad(),

  739.         'desc_inputs': [[2, 3], [2, 3]],

  740.         'skip': ['backward']}),

  741.     ('Atanh', {

  742.         'block': P.Atanh(),

  743.         'desc_inputs': [[2, 3]],

  744.         'desc_bprop': [[2, 3]]}),

  745.     ('Cosh', {

  746.         'block': P.Cosh(),

  747.         'desc_inputs': [[3, 4, 5]],

  748.         'desc_bprop': [[3, 4, 5]]}),

  749.     ('Sinh', {

  750.         'block': P.Sinh(),

  751.         'desc_inputs': [[3, 4, 5]],

  752.         'desc_bprop': [[3, 4, 5]]}),

  753.     ('Inv', {

  754.         'block': P.Inv(),

  755.         'desc_inputs': [[21, 9, 12, 5]],

  756.         'desc_bprop': [[21, 9, 12, 5]]}),

  757.     ('Invert', {

  758.         'block': P.Invert(),

  759.         'desc_inputs': [Tensor(np.array([[24, 4, 13, 9], [1, 5, 10, 8]]).astype(np.int16))],

  760.         'desc_bprop': [],

  761.         'skip': ['backward']}),

  762. ]

  763. 

  764. test_case_nn_ops = [

  765.     ('BiasAdd', {

  766.         'block': P.BiasAdd(),

  767.         'desc_inputs': [[1, 3, 3, 3], [3]],

  768.         'desc_bprop': [[1, 3, 3, 3]]}),

  769.     ('BiasAddGrad', {

  770.         'block': G.BiasAddGrad(),

  771.         'desc_inputs': [[1, 3, 3, 3]],

  772.         'skip': ['backward']}),

  773.     ('Gelu', {

  774.         'block': P.Gelu(),

  775.         'desc_inputs': [[1, 3, 4, 4]],

  776.         'desc_bprop': [[1, 3, 4, 4]]}),

  777.     ('GeluGrad', {

  778.         'block': G.GeluGrad(),

  779.         'desc_inputs': [[2, 2], [2, 2], [2, 2]],

  780.         'desc_bprop': [[2, 2]],

  781.         'skip': ['backward']}),

  782.     ('Tanh', {

  783.         'block': P.Tanh(),

  784.         'desc_inputs': [[1, 3, 4, 4]],

  785.         'desc_bprop': [[1, 3, 4, 4]]}),

  786.     ('TanhGrad', {

  787.         'block': G.TanhGrad(),

  788.         'desc_inputs': [[1, 3, 4, 4], [1, 3, 4, 4]],

  789.         'desc_bprop': [[1, 3, 4, 4]],

  790.         'skip': ['backward']}),

  791.     ('ReLU', {

  792.         'block': P.ReLU(),

  793.         'desc_inputs': [[1, 3, 4, 4]],

  794.         'desc_bprop': [[1, 3, 4, 4]]}),

  795.     ('ReLU6', {

  796.         'block': P.ReLU6(),

  797.         'desc_inputs': [[1, 3, 4, 4]],

  798.         'desc_bprop': [[1, 3, 4, 4]]}),

  799.     ('ReLUV2', {

  800.         'block': P.ReLUV2(),

  801.         'desc_inputs': [[1, 3, 4, 4]],

  802.         'desc_bprop': [[1, 3, 4, 4], ([1, 1, 4, 4, 2], {'dtype': np.uint8})]}),

  803.     ('ReLUGrad', {

  804.         'block': G.ReluGrad(),

  805.         'desc_inputs': [[1, 3, 4, 4], [1, 3, 4, 4]],

  806.         'skip': ['backward']}),

  807.     ('Softplus', {

  808.         'block': P.Softplus(),

  809.         'desc_inputs': [[1, 3, 4, 4]],

  810.         'desc_bprop': [[1, 3, 4, 4]]}),

  811.     ('SoftplusGrad', {

  812.         'block': G.SoftplusGrad(),

  813.         'desc_inputs': [[1, 3, 4, 4], [1, 3, 4, 4]],

  814.         'skip': ['backward']}),

  815.     ('Elu', {

  816.         'block': P.Elu(),

  817.         'desc_inputs': [[2, 3, 4]],

  818.         'desc_bprop': [[2, 3, 4]]}),

  819.     ('EluGrad', {

  820.         'block': G.EluGrad(),

  821.         'desc_inputs': [[2, 3, 4], [2, 3, 4]],

  822.         'desc_bprop': [[2, 3, 4]],

  823.         'skip': ['backward']}),

  824.     ('Sigmoid', {

  825.         'block': P.Sigmoid(),

  826.         'desc_inputs': [[1, 3, 4, 4]],

  827.         'desc_bprop': [[1, 3, 4, 4]]}),

  828.     ('MaxPool', {

  829.         'block': P.MaxPool(ksize=(2, 2), strides=(2, 2), padding="VALID"),

  830.         'desc_inputs': [[100, 3, 28, 28]],

  831.         'desc_bprop': [[100, 3, 14, 14]]}),

  832.     ('MaxPoolGrad', {

  833.         'block': G.MaxPoolGrad(ksize=(2, 2), strides=(2, 2), padding="VALID"),

  834.         'desc_inputs': [[3, 4, 6, 6], [3, 4, 3, 3], [3, 4, 3, 3]],

  835.         'desc_bprop': [[3, 4, 6, 6]],

  836.         'skip': ['backward']}),

  837.     ('AvgPool', {

  838.         'block': P.AvgPool(ksize=(2, 2), strides=(2, 2), padding="VALID"),

  839.         'desc_inputs': [[100, 3, 28, 28]],

  840.         'desc_bprop': [[100, 3, 14, 14]]}),

  841.     ('AvgPoolGrad', {

  842.         'block': G.AvgPoolGrad(ksize=(2, 2), strides=(2, 2), padding="VALID"),

  843.         'desc_const': [(3, 4, 6, 6)],

  844.         'const_first': True,

  845.         'desc_inputs': [[3, 4, 6, 6]],

  846.         'desc_bprop': [[3, 4, 6, 6]],

  847.         'skip': ['backward']}),

  848.     ('MaxPoolWithArgmax', {

  849.         'block': P.MaxPoolWithArgmax(ksize=2, strides=2),

  850.         'desc_inputs': [[128, 32, 32, 64]],

  851.         'desc_bprop': [[128, 32, 16, 32], ([128, 32, 4, 33], {'dtype': np.uint16})]}),

  852.     ('SoftmaxCrossEntropyWithLogits', {

  853.         'block': P.SoftmaxCrossEntropyWithLogits(),

  854.         'desc_inputs': [[1, 10], [1, 10]],

  855.         'desc_bprop': [[1], [1, 10]],

  856.         'skip': ['backward_exec']}),

  857.     ('Flatten', {

  858.         'block': P.Flatten(),

  859.         'desc_inputs': [[128, 32, 32, 64]],

  860.         'desc_bprop': [[128, 65536]]}),

  861.     ('LogSoftmax', {

  862.         'block': P.LogSoftmax(),

  863.         'desc_inputs': [[64, 2]],

  864.         'desc_bprop': [[64, 2]]}),

  865.     ('LogSoftmaxGrad', {

  866.         'block': G.LogSoftmaxGrad(),

  867.         'desc_inputs': [[16, 1234], [16, 1234]],

  868.         'desc_bprop': [[64, 2]],

  869.         'skip': ['backward']}),

  870.     ('L2Normalize', {

  871.         'block': P.L2Normalize(),

  872.         'desc_inputs': [[2, 2]],

  873.         'desc_bprop': [[2, 2]]}),

  874.     ('L2NormalizeGrad', {

  875.         'block': G.L2NormalizeGrad(),

  876.         'desc_inputs': [[2, 2], [2, 2], [2, 2]],

  877.         'desc_bprop': [[2, 2]],

  878.         'skip': ['backward']}),

  879.     ('LayerNorm', {

  880.         'block': P.LayerNorm(),

  881.         'desc_inputs': [[2, 16], [16], [16]],

  882.         'desc_bprop': [[2, 16], [2, 1], [2, 1]]}),

  883.     ('LayerNormGrad', {

  884.         'block': G.LayerNormGrad(),

  885.         'desc_inputs': [[2, 16], [2, 16], [2, 16], [2, 16], [16]],

  886.         'desc_bprop': [[2, 16], [16], [16]],

  887.         'skip': ['backward']}),

  888.     ('FusedBatchNorm', {

  889.         'block': P.FusedBatchNorm(),

  890.         'desc_inputs': [[128, 64, 32, 64], [64], [64], [64], [64]],

  891.         'desc_bprop': [[128, 64, 32, 64], [64], [64], [64], [64]],

  892.         'skip': []}),

  893.     ('FusedBatchNormGrad', {

  894.         'block': G.FusedBatchNormGrad(),

  895.         'desc_inputs': [[128, 64, 32, 64], [128, 64, 32, 64], [64], [64], [64]],

  896.         'desc_bprop': [[128, 64, 32, 64], [64], [64], [64], [64]],

  897.         'skip': ['backward']}),

  898.     ('BatchNorm', {

  899.         'block': P.BatchNorm(),

  900.         'desc_inputs': [[128, 64, 32, 32], [64], [64], [64], [64]],

  901.         'desc_bprop': [[128, 64, 32, 32], [64], [64], [64], [64]],

  902.         'skip': []}),

  903.     ('BatchNormGrad', {

  904.         'block': G.BatchNormGrad(),

  905.         'desc_inputs': [[128, 64, 32, 32], [128, 64, 32, 32], [64], [64], [64]],

  906.         'desc_bprop': [[128, 64, 32, 32], [64], [64], [64], [64]],

  907.         'skip': ['backward']}),

  908.     ('BasicLSTMCell', {

  909.         'block': P.BasicLSTMCell(keep_prob=1.0, forget_bias=1.0, state_is_tuple=True, activation='tanh'),

  910.         'desc_inputs': [[128, 128], [128, 128], [128, 128], [512, 256, 1, 1],[512, 1, 1, 1]],

  911.         'desc_bprop': [[128, 128], [128, 128], [128, 128], [128, 128], [128, 128], [128, 128], [128, 128]],

  912.         'skip': []}),

  913.     ('TopK', {

  914.         'block': P.TopK(),

  915.         'desc_const': [5],

  916.         'desc_inputs': [[20, 20, 10]],

  917.         'desc_bprop': [[20, 20, 5]],

  918.         'skip': ['backward']}),

  919.     ('GatherV2_0', {

  920.         'block': P.GatherV2(),

  921.         'desc_const': [0],

  922.         'desc_inputs': [[3, 1, 2], Tensor(np.array([0, 1]).astype(np.int32))],

  923.         'desc_bprop': [[2, 1, 2]]}),

  924.     ('GatherV2_1', {

  925.         'block': P.GatherV2(),

  926.         'desc_const': [2],

  927.         'desc_inputs': [[3, 1, 3], Tensor(np.array([0, 1]).astype(np.int32))],

  928.         'desc_bprop': [[3, 1, 2]]}),

  929.     ('GatherV2_2', {

  930.         'block': P.GatherV2(),

  931.         'desc_const': [0],

  932.         'desc_inputs': [[3, 1, 3], Tensor(np.array([[0, 1], [0, 1], [0, 1]]).astype(np.int32))],

  933.         'desc_bprop': [[3, 2, 1, 3]]}),

  934.     ('GatherV2_3', {

  935.         'block': P.GatherV2(),

  936.         'desc_const': [2],

  937.         'desc_inputs': [[3, 1, 3], Tensor(np.array([[0, 1], [0, 1], [0, 1]]).astype(np.int32))],

  938.         'desc_bprop': [[3, 1, 3, 2]]}),

  939.     ('GatherV2_4', {

  940.         'block': P.GatherV2(),

  941.         'desc_const': [1],

  942.         'desc_inputs': [[32, 5, 1024], Tensor(np.array([3]).astype(np.int32))],

  943.         'desc_bprop': [[32, 1, 1024]]}),

  944.     ('GatherV2_5', {

  945.         'block': P.GatherV2(),

  946.         'desc_const': [-1],

  947.         'desc_inputs': [[3, 1, 3], Tensor(np.array([0, 1]).astype(np.int32))],

  948.         'desc_bprop': [[3, 1, 2]]}),

  949.     ('GatherV2_6', {

  950.         'block': P.GatherV2(),

  951.         'desc_const': [0],

  952.         'desc_inputs': [[1152], Tensor(np.array(10).astype(np.int32))],

  953.         'desc_bprop': [Tensor(np.array(10).astype(np.float32))]}),

  954.     ('Range', {

  955.         'block': P.Range(1.0, 5.0),

  956.         'desc_inputs': [Tensor(np.ones([10]).astype(np.float32))],

  957.         'desc_bprop': [[10]]}),

  958.     ('UnsortedSegmentSum', {

  959.         'block': P.UnsortedSegmentSum(),

  960.         'desc_const': [1280],

  961.         'desc_inputs': [[1280, 1024], Tensor(np.ones(1280).astype(np.int32))],

  962.         'desc_bprop': [[8192, 1024]],

  963.         'skip': ['backward']}),

  964.     ('UnsortedSegmentSum_1', {

  965.         'block': P.UnsortedSegmentSum(),

  966.         'desc_const': [4],

  967.         'desc_inputs': [[3, 2, 1, 3], Tensor(np.array([[0, 1], [0, 1], [0, 1]]).astype(np.int32))],

  968.         'desc_bprop': [[4, 1, 3]],

  969.         'skip': ['backward']}),

  970.     ('UnsortedSegmentMin', {

  971.         'block': P.UnsortedSegmentMin(),

  972.         'desc_const': [4],

  973.         'desc_inputs': [[3, 2, 1, 3], Tensor(np.array([1, 2, 3]).astype(np.int32))],

  974.         'desc_bprop': [[4, 2, 1, 3]]}),

  975.     ('DropoutGenMask', {

  976.         'block': P.DropoutGenMask(),

  977.         'desc_const': [(2, 2), Tensor(0.5, mstype.float32)],

  978.         'desc_inputs': [],

  979.         'desc_bprop': [Tensor(np.ones(1).astype(np.int8))],

  980.         'skip': ['backward']}),

  981.     ('DropoutDoMask', {

  982.         'block': P.DropoutDoMask(),

  983.         'desc_const': [Tensor(0.5)],

  984.         'desc_inputs': [[64, 12, 128, 128], Tensor(np.ones(1572864).astype(np.uint8))],

  985.         'desc_bprop': [[64, 12, 128, 128]]}),

  986.     ('Dropout', {

  987.         'block': nn.Dropout(0.5),

  988.         'desc_inputs': [[64, 12, 128, 128]],

  989.         'desc_bprop': [[64, 12, 128, 128]]}),

  990.     ('ReduceMean0', {

  991.         'block': P.ReduceMean(),

  992.         'desc_const': [(2,)],

  993.         'desc_inputs': [[3, 2, 2]],

  994.         'desc_bprop': [[3, 2]]}),

  995.     ('ReduceMean1', {

  996.         'block': P.ReduceMean(),

  997.         'desc_const': [2],

  998.         'desc_inputs': [[3, 2, 2]],

  999.         'desc_bprop': [[3, 2]]}),

  1000.     ('All', {

  1001.         'block': P.ReduceAll(),

  1002.         'desc_const': [(1,)],

  1003.         'desc_inputs': [Tensor(np.ones([3, 2]).astype(np.bool_))],

  1004.         'desc_bprop': [[3]],

  1005.         'skip': ['backward']}),

  1006.     ('DescConst', {

  1007.         'block': Tensor(np.array([2], np.float32)),

  1008.         'desc_inputs': [],

  1009.         'desc_bprop': [[1]],

  1010.         'skip': ['backward'],

  1011.         'add_fake_input': True}),

  1012.     ('Fill', {

  1013.         'block': P.Fill(),

  1014.         'desc_const': [mstype.float32, (2, 3), 1.0],

  1015.         'desc_inputs': [],

  1016.         'desc_bprop': [[2, 3]],

  1017.         'skip': ['backward'],

  1018.         'add_fake_input': True}),

  1019.     ('OnesLike', {

  1020.         'block': P.OnesLike(),

  1021.         'desc_inputs': [Tensor(np.array([[0, 1], [2, 1]]).astype(np.int32))],

  1022.         'desc_bprop': [Tensor(np.array([[1, 1], [1, 1]]).astype(np.int32))]

  1023.     }),

  1024.     ('ZerosLike', {

  1025.         'block': P.ZerosLike(),

  1026.         'desc_inputs': [Tensor(np.array([[0, 1], [2, 1]]).astype(np.int32))],

  1027.         'desc_bprop': [Tensor(np.array([[1, 1], [1, 1]]).astype(np.int32))]

  1028.     }),

  1029.     ('Softmax', {

  1030.         'block': P.Softmax(),

  1031.         'desc_inputs': [[5, 5]],

  1032.         'desc_bprop': [[5, 5]]}),

  1033.     ('DepthwiseConv2dNative_1', {

  1034.         'block': P.DepthwiseConv2dNative(3, (3, 3), pad_mode="pad", pad=1, stride=2),

  1035.         'desc_inputs': [[10, 32, 32, 32], [1, 32, 3, 3]],

  1036.         'desc_bprop': [[10, 32, 16, 16]]}),

  1037.     ('DepthwiseConv2dNative_2', {

  1038.         'block': P.DepthwiseConv2dNative(1, (3, 3), pad_mode="same", pad=0, stride=1),

  1039.         'desc_inputs': [[2592, 2048, 4, 4], [1, 2048, 3, 3]],

  1040.         'desc_bprop': [[2592, 2048, 4, 4]]}),

  1041.     ('SigmoidCrossEntropyWithLogits', {

  1042.         'block': P.SigmoidCrossEntropyWithLogits(),

  1043.         'desc_inputs': [[128, 10], [128, 10]],

  1044.         'desc_bprop': [[128, 10]]}),

  1045.     ('Pad', {

  1046.         'block': P.Pad(((1, 2), (2, 3))),

  1047.         'desc_inputs': [[7, 7]],

  1048.         'desc_bprop': [[10, 12]]}),

  1049.     ('BinaryCrossEntropy', {

  1050.         'block': P.BinaryCrossEntropy(),

  1051.         'desc_inputs': [[1, 2, 3], [1, 2, 3], [1, 2, 3]],

  1052.         'desc_bprop': []}),

  1053.     ('SparseApplyAdagrad', {

  1054.         'block': P.SparseApplyAdagrad(0.5),

  1055.         'desc_inputs': [[3, 3], [3, 3], [3, 3], Tensor(np.ones((3,), np.int32))],

  1056.         'skip': ['backward']}),

  1057.     ('SparseApplyFtrl', {

  1058.         'block': SparseApplyFtrlNet(),

  1059.         'desc_inputs': [[3, 3], Tensor(np.ones((3,), np.int32))],

  1060.         'skip': ['backward']}),

  1061.     ('ApplyProximalAdagrad', {

  1062.         'block': ApplyProximalAdagradNet(),

  1063.         'desc_inputs': [[3, 3], [3, 3], [3, 3]],

  1064.         'skip': ['backward']}),

  1065.     ('SparseApplyProximalAdagrad', {

  1066.         'block': SparseApplyProximalAdagradNet(),

  1067.         'desc_inputs': [[3, 3], [3, 3], [3, 3], Tensor(np.ones((3,), np.int32))],

  1068.         'skip': ['backward']}),

  1069.     ('Flatten_1', {

  1070.         'block': NetForFlatten(),

  1071.         'desc_inputs': [Tensor(np.ones([2, 3, 4]).astype(np.int32)), Tensor(np.ones([2, 12]).astype(np.int32))],

  1072.         'desc_bprop': [Tensor(np.ones([2, 12]).astype(np.int32))],

  1073.         'skip': ['backward']}),

  1074.     ('Flatten_2', {

  1075.         'block': NetForFlatten(),

  1076.         'desc_inputs': [Tensor(np.ones([8]).astype(np.int32)), Tensor(np.ones([8, 3]).astype(np.int32))],

  1077.         'desc_bprop': [Tensor(np.ones([8, 3]).astype(np.int32))],

  1078.         'skip': ['backward']}),

  1079.     ('Flatten_3', {

  1080.         'block': NetForFlattenComposed(),

  1081.         'desc_inputs': [Tensor(np.ones([2, 3, 4]).astype(np.int32)), Tensor(np.ones([2, 12]).astype(np.int32))],

  1082.         'desc_bprop': [Tensor(np.ones([2, 12]).astype(np.int32))],

  1083.         'skip': []}),

  1084.     ('ArgmaxNet', {

  1085.         'block': ArgmaxNet(),

  1086.         'desc_inputs': [Tensor(np.array([[128, 32, 32, 64], [128, 32, 32, 64]]).astype(np.float16))],

  1087.         'desc_bprop': [Tensor(np.array([[128, 32, 32, 64], [128, 32, 32, 64]]).astype(np.float16))],

  1088.         'skip': ['backward']}),

  1089.     ('ArgminNet', {

  1090.         'block': ArgminNet(),

  1091.         'desc_inputs': [Tensor(np.array([[128, 32, 32, 64], [128, 32, 32, 64]]).astype(np.float16))],

  1092.         'desc_bprop': [Tensor(np.array([[128, 32, 32, 64], [128, 32, 32, 64]]).astype(np.float16))],

  1093.         'skip': ['backward']}),

  1094.     ('OneHot', {

  1095.         'block': P.OneHot(),

  1096.         'desc_const': [3, Tensor(1.0, mstype.float32), Tensor(0.0, mstype.float32)],

  1097.         'desc_inputs': [Tensor(np.array([64]).astype(np.int32))],

  1098.         'desc_bprop': [[1, 3]]}),

  1099.     ('ReduceProd_0', {

  1100.         'block': P.ReduceProd(),

  1101.         'desc_const': [0],

  1102.         'desc_inputs': [[3, 2]],

  1103.         'desc_bprop': [[2]]}),

  1104.     ('ReduceProd_1', {

  1105.         'block': P.ReduceProd(keep_dims=True),

  1106.         'desc_const': [0],

  1107.         'desc_inputs': [[3, 2]],

  1108.         'desc_bprop': [[1, 2]]}),

  1109.     ('CumProd', {

  1110.         'block': P.CumProd(),

  1111.         'desc_const': [0],

  1112.         'desc_inputs': [[3, 2]],

  1113.         'desc_bprop': [[3, 2]]}),

  1114.     ('ApplyFtrl', {

  1115.         'block': ApplyFtrlNet(),

  1116.         'desc_inputs': [[3, 3]],

  1117.         'desc_bprop': [3, 3],

  1118.         'skip': ['backward']}),

  1119.     ('ApplyRMSProp', {

  1120.         'block': ApplyRMSNet(),

  1121.         'desc_inputs': [[3, 3]],

  1122.         'desc_bprop': [3, 3],

  1123.         'skip': ['backward']}),

  1124.     ('ApplyCenteredRMSProp', {

  1125.         'block': P.ApplyCenteredRMSProp(),

  1126.         'desc_const': [0.9, 0.0, 1e-10, 0.001],

  1127.         'desc_inputs': [Tensor(1., mstype.float32), Tensor(2., mstype.float32), Tensor(1., mstype.float32),

  1128.                         Tensor(2., mstype.float32), Tensor(1., mstype.float32)],

  1129.         'desc_bprop': [1],

  1130.         'skip': ['backward']}),

  1131.     ('CTCLoss', {

  1132.         'block': P.CTCLoss(),

  1133.         'desc_inputs': [Tensor(np.ones([6, 4, 6]).astype(np.float32)),

  1134.                         Tensor(np.array([[0, 1], [1, 0], [2, 3], [3, 2]]).astype(np.int64)),

  1135.                         Tensor(np.array([1, 2, 3, 4]).astype(np.int32)),

  1136.                         Tensor(np.array([6, 6, 6, 6]).astype(np.int32))],

  1137.         'desc_bprop': [[4], [6, 4, 6]]}),

  1138.     ('L2Loss_1', {

  1139.         'block': P.L2Loss(),

  1140.         'desc_inputs': [Tensor(np.array([1, 2, 3, 4]), mstype.float32)],

  1141.         'desc_bprop': []}),

  1142.     ('L2Loss_2', {

  1143.         'block': P.L2Loss(),

  1144.         'desc_inputs': [Tensor(np.array([[1, 1], [2, 2], [3, 3], [4, 4]]), mstype.float16)],

  1145.         'desc_bprop': []}),

  1146.     ('ResizeBilinear', {

  1147.         'block': P.ResizeBilinear((5, 5)),

  1148.         'desc_inputs': [Tensor([[[[1, 2, 3, 4, 5], [1, 2, 3, 4, 5]]]], mstype.float16)],

  1149.         'desc_bprop': [Tensor([[[[1, 2, 3, 4, 5], [1, 2, 3, 4, 5]]]], mstype.float16)]}),

  1150.     ('ResizeBilinearGrad', {

  1151.         'block': G.ResizeBilinearGrad(),

  1152.         'desc_inputs': [Tensor([[[[1, 2, 3, 4, 5]]]], mstype.float32), Tensor([[[[1, 2, 3, 4, 5]]]], mstype.float32)],

  1153.         'desc_bprop': [Tensor([[[[1, 2, 3, 4, 5]]]], mstype.float32)],

  1154.         'skip': ['backward']}),

  1155.     ('ROIAlign', {

  1156.         'block': P.ROIAlign(7, 7, 0.03125, 2),

  1157.         'desc_inputs': [[2, 256, 192, 320], [1024, 5]],

  1158.         'desc_bprop': [[7, 7]]}),

  1159.     ('ROIAlignGrad', {

  1160.         'block': G.ROIAlignGrad((1, 1, 1, 1), 2, 2, 0.5, 2),

  1161.         'desc_inputs': [[1, 1, 2, 2], [1, 5]],

  1162.         'desc_bprop': [[1, 1, 2, 2]],

  1163.         'skip': ['backward']}),

  1164.     ('LARSUpdate', {

  1165.         'block': P.LARSUpdate(1e-05, 0.001, False),

  1166.         'desc_const': [0.0, 0.001],

  1167.         'desc_inputs': [[3, 3], [3, 3], [3, 3], [3, 3]],

  1168.         'desc_bprop': [3, 3],

  1169.         'skip': ['backward']}),

  1170.     ('SGD', {

  1171.         'block': P.SGD(0.0, 0.0, False),

  1172.         'desc_inputs': [[3, 3], [3, 3], Tensor(0.001, mstype.float32), [3, 3], Tensor(0.1, mstype.float32), [3, 3]],

  1173.         'desc_bprop': [3, 3],

  1174.         'skip': ['backward']}),

  1175.     ('BinaryCrossEntropy', {

  1176.         'block': P.BinaryCrossEntropy(),

  1177.         'desc_inputs': [Tensor([[0.3, 0.8], [0.4, 0.3]], mstype.float16),

  1178.                         Tensor([[0.4, 1.2], [-0.4, -0.9]], mstype.float16),

  1179.                         Tensor([[-1.4, -0.7], [0.9, 0.7]], mstype.float16)],

  1180.         'desc_bprop': []}),

  1181.     ('BinaryCrossEntropyGrad', {

  1182.         'block': G.BinaryCrossEntropyGrad(),

  1183.         'desc_inputs': [Tensor([[0.3, 0.8], [0.4, 0.3]], mstype.float16),

  1184.                         Tensor([[0.4, 1.2], [-0.4, -0.9]], mstype.float16), Tensor(0.85, mstype.float16),

  1185.                         Tensor([[-1.4, -0.7], [0.9, 0.7]], mstype.float16)],

  1186.         'desc_bprop': [],

  1187.         'skip': ['backward']}),

  1188.     ('SparseApplyAdagrad', {

  1189.         'block': P.SparseApplyAdagrad(0.5),

  1190.         'desc_inputs': [Tensor([[0.7, 0.2], [0.1, 0.07]], mstype.float32),

  1191.                         Tensor([[0.2, 0.2], [0.1, 0.4]], mstype.float32),

  1192.                         Tensor([[0.5, 0.4], [0.6, 0.1]], mstype.float32), Tensor([1, 1], mstype.int32)],

  1193.         'desc_bprop': [Tensor([[0.7, 0.2], [0.1, 0.07]], mstype.float32)],

  1194.         'skip': ['backward']}),

  1195. ]

  1196. 

  1197. test_case_array_ops = [

  1198.     ('SpaceToDepth', {

  1199.         'block': P.SpaceToDepth(2),

  1200.         'desc_inputs': [[1, 3, 2, 2]],

  1201.         'desc_bprop': [[1, 12, 1, 1]]}),

  1202.     ('DepthToSpace', {

  1203.         'block': P.DepthToSpace(2),

  1204.         'desc_inputs': [[1, 12, 1, 1]],

  1205.         'desc_bprop': [[1, 3, 2, 2]]}),

  1206.     ('Split', {

  1207.         'block': P.Split(1, 2),

  1208.         'desc_inputs': [Tensor(np.array([[1, 1, 1, 1], [2, 2, 2, 2]]))],

  1209.         'skip': ['backward']}),

  1210.     ('Argmax', {

  1211.         'block': P.Argmax(),

  1212.         'desc_inputs': [[128, 32, 32, 64]],

  1213.         'desc_bprop': [0],

  1214.         'skip': ['backward']}),

  1215.     ('Argmin', {

  1216.         'block': P.Argmin(),

  1217.         'desc_inputs': [[128, 32, 32, 64]],

  1218.         'desc_bprop': [1],

  1219.         'skip': ['backward']}),

  1220.     ('ArgMaxWithValue', {

  1221.         'block': P.ArgMaxWithValue(),

  1222.         'desc_inputs': [[128, 32, 32, 64]],

  1223.         'desc_bprop': [[1], [1]],

  1224.         'skip': ['backward']}),

  1225.     ('ArgMinWithValue', {

  1226.         'block': P.ArgMinWithValue(),

  1227.         'desc_inputs': [[128, 32, 32, 64]],

  1228.         'desc_bprop': [[1], [1]],

  1229.         'skip': ['backward']}),

  1230.     ('Transpose_dim3', {

  1231.         'block': P.Transpose(),

  1232.         'desc_const': [(0, 2, 1)],

  1233.         'desc_inputs': [[1, 2, 3]],

  1234.         'desc_bprop': [[1, 3, 2]]}),

  1235.     ('Transpose_dim4', {

  1236.         'block': P.Transpose(),

  1237.         'desc_const': [(0, 1, 2, 3)],

  1238.         'desc_inputs': [[1, 2, 3, 4]],

  1239.         'desc_bprop': [[1, 2, 4, 3]]}),

  1240.     ('AddN', {

  1241.         'block': NetForTupleInput(P.AddN()),

  1242.         'desc_inputs': [[2, 3, 3, 5], [2, 3, 3, 5]],

  1243.         'desc_bprop': [[2, 3, 3, 5]],

  1244.         'skip': ['backward']}),

  1245.     ('Shape', {

  1246.         'block': P.Shape(),

  1247.         'desc_inputs': [[3, 3, 2, 2]],

  1248.         'skip': ['backward']}),

  1249.     ('Reshape', {

  1250.         'block': P.Reshape(),

  1251.         'desc_const': [(64,)],

  1252.         'desc_inputs': [[64, 1]],

  1253.         'desc_bprop': [[64]]}),

  1254.     ('Cast', {

  1255.         'block': P.Cast(),

  1256.         'desc_const': [mstype.int32],

  1257.         'desc_inputs': [[2, 3, 4, 5]],

  1258.         'desc_bprop': [Tensor(np.ones((2, 3, 4, 5)).astype(np.int32))]}),

  1259.     ('ExpandDims', {

  1260.         'block': P.ExpandDims(),

  1261.         'desc_const': [0],

  1262.         'desc_inputs': [[2, 2]],

  1263.         'desc_bprop': [[1, 2, 2]]}),

  1264.     ('ExpandDims_1', {

  1265.         'block': P.ExpandDims(),

  1266.         'desc_const': [-1],

  1267.         'desc_inputs': [[2, 2]],

  1268.         'desc_bprop': [[2, 2, 1]]}),

  1269.     ('Squeeze', {

  1270.         'block': P.Squeeze(2),

  1271.         'desc_inputs': [[3, 2, 1]],

  1272.         'desc_bprop': [[3, 2]]}),

  1273.     ('Squeeze_0', {

  1274.         'block': P.Squeeze(),

  1275.         'desc_inputs': [[3, 1, 2, 1]],

  1276.         'desc_bprop': [[3, 2]]}),

  1277.     ('Squeeze_1', {

  1278.         'block': P.Squeeze(),

  1279.         'desc_inputs': [[1, 1, 1, 1]],

  1280.         'desc_bprop': [1.0],

  1281.         'skip': ['backward']}),

  1282.     ('Squeeze_2', {

  1283.         'block': P.Squeeze((2, 3)),

  1284.         'desc_inputs': [[3, 2, 1, 1]],

  1285.         'desc_bprop': [[3, 2]]}),

  1286.     ('Size', {

  1287.         'block': P.Size(),

  1288.         'desc_inputs': [[2, 3, 5]],

  1289.         'skip': ['backward']}),

  1290.     ('Tile_0', {

  1291.         'block': P.Tile(),

  1292.         'desc_const': [(1, 2)],

  1293.         'desc_inputs': [[64, 1]],

  1294.         'desc_bprop': [[64, 2]]}),

  1295.     ('Tile_1', {

  1296.         'block': P.Tile(),

  1297.         'desc_const': [(1, 1)],

  1298.         'desc_inputs': [[64, 1]],

  1299.         'desc_bprop': [[64, 1]]}),

  1300.     ('Tile_2', {

  1301.         'block': P.Tile(),

  1302.         'desc_const': [(2, 1, 1, 2)],

  1303.         'desc_inputs': [[2, 2, 2]],

  1304.         'desc_bprop': [[2, 2, 2, 4]]}),

  1305.     ('ConcatV2_0', {

  1306.         'block': P.Concat(),

  1307.         'desc_inputs': [

  1308.             (Tensor(np.array([[0, 1], [2, 1]]).astype(np.int32)),

  1309.              Tensor(np.array([[0, 1], [2, 1]]).astype(np.int32)))],

  1310.         'desc_bprop': [([4, 2], {'dtype': np.int32})]}),

  1311.     ('ConcatV2_1', {

  1312.         'block': P.Concat(axis=2),

  1313.         'desc_inputs': [(Tensor(np.array([[[0, 1, 2]], [[2, 1, 2]]]).astype(np.int32)),

  1314.                          Tensor(np.array([[[0, 1]], [[2, 1]]]).astype(np.int32)))],

  1315.         'desc_bprop': [([2, 1, 5], {'dtype': np.int32})]}),

  1316.     ('ConcatV2_2', {

  1317.         'block': NetForConcat(),

  1318.         'desc_inputs': [[2, 2]],

  1319.         'desc_bprop': [[4, 2]]}),

  1320.     ('ConcatV2_3', {

  1321.         'block': NetForConcat1(),

  1322.         'desc_inputs': [[2, 2], [2, 2]],

  1323.         'desc_bprop': [[4, 2]]}),

  1324.     ('ConcatV2_4', {

  1325.         'block': P.Concat(axis=0),

  1326.         'desc_inputs': [

  1327.             (Tensor(np.ones((3, 2, 3), np.float32)),

  1328.              Tensor(np.ones((5, 2, 3), np.float32)),

  1329.              Tensor(np.ones((6, 2, 3), np.float32)))],

  1330.         'desc_bprop': [[14, 2, 3]]}),

  1331.     ('ConcatV2_5', {

  1332.         'block': P.Concat(axis=-1),

  1333.         'desc_inputs': [(Tensor(np.array([1], np.float32)),

  1334.                          Tensor(np.array([1], np.float32)),

  1335.                          Tensor(np.array([1], np.float32)))],

  1336.         'desc_bprop': [[3, ]]}),

  1337.     ('Pack_0', {

  1338.         'block': NetForPackInput(P.Pack()),

  1339.         'desc_inputs': [[2, 2], [2, 2], [2, 2]],

  1340.         'desc_bprop': [[3, 2, 2]],

  1341.     }),

  1342.     ('Pack_1', {

  1343.         'block': NetForPackInput(P.Pack(axis=-2)),

  1344.         'desc_inputs': [[3, 2, 3], [3, 2, 3], [3, 2, 3]],

  1345.         'desc_bprop': [[3, 2, 3, 3]],

  1346.     }),

  1347.     ('Pack_2', {

  1348.         'block': NetForPackInput(P.Pack()),

  1349.         'desc_inputs': [[128, 128], [128, 128]],

  1350.         'desc_bprop': [[2, 128, 128]],

  1351.     }),

  1352.     ('Unpack_0', {

  1353.         'block': NetForUnpackInput(P.Unpack(axis=0)),

  1354.         'desc_inputs': [[2, 4]],

  1355.         'desc_bprop': [[4], [4]],

  1356.     }),

  1357.     ('Unpack_1', {

  1358.         'block': NetForUnpackInput(P.Unpack(axis=-1)),

  1359.         'desc_inputs': [Tensor(np.array([[1, 1, 1]], np.float32))],

  1360.         'desc_bprop': [[1], [1], [1]],

  1361.     }),

  1362.     ('Diag_1', {

  1363.         'block': P.Diag(),

  1364.         'desc_inputs': [[4]],

  1365.         'desc_bprop': [[4, 4]],

  1366.     }),

  1367.     ('Diag_2', {

  1368.         'block': P.Diag(),

  1369.         'desc_inputs': [[4, 4]],

  1370.         'desc_bprop': [[4, 4, 4, 4]],

  1371.     }),

  1372.     ('DiagPart_1', {

  1373.         'block': P.DiagPart(),

  1374.         'desc_inputs': [[4, 4]],

  1375.         'desc_bprop': [[4]],

  1376.     }),

  1377.     ('DiagPart_2', {

  1378.         'block': P.DiagPart(),

  1379.         'desc_inputs': [[4, 4, 4, 4]],

  1380.         'desc_bprop': [[4, 4]],

  1381.     }),

  1382.     ('SpaceToBatch_1', {

  1383.         'block': P.SpaceToBatch(2, [[0, 0], [0, 0]]),

  1384.         'desc_inputs': [[1, 3, 2, 2]],

  1385.         'desc_bprop': [[4, 3, 1, 1]],

  1386.     }),

  1387.     ('SpaceToBatch_2', {

  1388.         'block': P.SpaceToBatch(2, [[1, 1], [0, 4]]),

  1389.         'desc_inputs': [[1, 3, 2, 2]],

  1390.         'desc_bprop': [[4, 3, 2, 3]],

  1391.     }),

  1392.     ('BatchToSpace_1', {

  1393.         'block': P.BatchToSpace(2, [[0, 0], [0, 0]]),

  1394.         'desc_inputs': [[4, 3, 1, 1]],

  1395.         'desc_bprop': [[1, 3, 2, 2]],

  1396.     }),

  1397.     ('BatchToSpace_2', {

  1398.         'block': P.BatchToSpace(2, [[0, 0], [0, 1]]),

  1399.         'desc_inputs': [[4, 3, 1, 1]],

  1400.         'desc_bprop': [[1, 3, 2, 1]],

  1401.     }),

  1402.     ('UnsortedSegmentMin_1', {

  1403.         'block': P.UnsortedSegmentMin(),

  1404.         'desc_const': [2],

  1405.         'desc_inputs': [Tensor(np.array([[1, 2, 3], [4, 5, 6], [4, 2, 1]]).astype(np.float32)),

  1406.                         Tensor(np.array([0, 1, 1]).astype(np.int32))],

  1407.         'desc_bprop': [Tensor(np.array([[1, 2, 3], [4, 2, 1]]).astype(np.float32))]}),

  1408. ]

  1409. 

  1410. test_case_other_ops = [

  1411.     ('ScalarLog', {

  1412.         'block': F.scalar_log,

  1413.         'desc_const': [0.0],

  1414.         'desc_inputs': [],

  1415.         'desc_bprop': [1],

  1416.         'skip': ['backward']}),

  1417.     ('BoundingBoxEncode', {

  1418.         'block': P.BoundingBoxEncode(means=(0.0, 0.0, 0.0, 0.0), stds=(1.0, 1.0, 1.0, 1.0)),

  1419.         'desc_inputs': [[256, 4], [256, 4]],

  1420.         'desc_bprop': [[256, 4]],

  1421.         'skip': ['backward']}),

  1422.     ('BoundingBoxDecode', {

  1423.         'block': P.BoundingBoxDecode(means=(0.0, 0.0, 0.0, 0.0), stds=(1.0, 1.0, 1.0, 1.0), max_shape=(768, 1280)),

  1424.         'desc_inputs': [[256, 4], [256, 4]],

  1425.         'desc_bprop': [[256, 4]],

  1426.         'skip': ['backward']}),

  1427.     ('GatherNd', {

  1428.         'block': P.GatherNd(),

  1429.         'desc_inputs': (Tensor(np.ones((1, 3, 6, 6), np.float32)),

  1430.                         Tensor(np.ones((2, 4), np.int32))),

  1431.         'desc_bprop': [[2]]}),

  1432.     ('ScatterNd', {

  1433.         'block': P.ScatterNd(),

  1434.         'desc_const': [(3, 3)],

  1435.         'desc_inputs': (Tensor(np.ones((2, 2), np.int32)),

  1436.                         Tensor(np.ones((2,), np.int32))),

  1437.         'desc_bprop': [([3, 3], {'dtype': np.int32})]}),

  1438.     ('ScatterMax', {

  1439.         'block': ScatterMax(),

  1440.         'desc_inputs': (Tensor(np.array([[0, 0], [1, 1]], np.int32)),

  1441.                         Tensor(np.ones([2, 2, 3], np.float32) * 99)),

  1442.         'skip': ['backward']}),

  1443.     ('ScatterAdd', {

  1444.         'block': ScatterAdd((6,)),

  1445.         'desc_inputs': (Tensor(np.array([2, 0, 5], np.int32)),

  1446.                         Tensor(np.array([2.0, 3.0, 4.0], np.float32))),

  1447.         'skip': ['backward']}),

  1448.     ('ScatterAdd2d', {

  1449.         'block': ScatterAdd((3, 4)),

  1450.         'desc_inputs': (Tensor(np.array([[0, 1], [1, 2]], np.int32)),

  1451.                         Tensor(np.array([[[1, 1, 1, 1], [2, 2, 2, 2]],

  1452.                                          [[3, 3, 3, 3], [4, 4, 4, 4]]], np.float32))),

  1453.         'skip': ['backward']}),

  1454.     ('SmoothL1Loss', {

  1455.         'block': P.SmoothL1Loss(),

  1456.         'desc_inputs': [[256, 4], [256, 4]],

  1457.         'desc_bprop': [[256, 4]]}),

  1458.     ('IOU', {

  1459.         'block': P.IOU(),

  1460.         'desc_inputs': [Tensor(np.ones((256, 4), np.float16)), Tensor(np.ones((128, 4), np.float16))],

  1461.         'desc_bprop': [[128, 256]]}),

  1462.     ('Summary', {

  1463.         'block': SummaryNet(),

  1464.         'desc_inputs': [Tensor(np.array([1.1]).astype(np.float32)),

  1465.                         Tensor(np.array([1.2]).astype(np.float32))],

  1466.         'skip': ['backward']}),

  1467.     ('ConfusionMulGrad_1', {

  1468.         'block': P.ConfusionMulGrad(axis=[0], keep_dims=False),

  1469.         'desc_inputs': [[3, 2], [3, 2], [3, 2]],

  1470.         'desc_bprop': [[3, 2], [2]],

  1471.         'skip': ['backward']}),

  1472.     ('ConfusionMulGrad_2', {

  1473.         'block': P.ConfusionMulGrad(axis=[0], keep_dims=True),

  1474.         'desc_inputs': [[3, 2], [3, 2], [3, 2]],

  1475.         'desc_bprop': [[3, 2], [1, 2]],

  1476.         'skip': ['backward']}),

  1477.     ('ConfusionMulGrad_3', {

  1478.         'block': P.ConfusionMulGrad(axis=(), keep_dims=True),

  1479.         'desc_inputs': [[2, 3, 4], [2, 3, 4], [2, 3, 4]],

  1480.         'desc_bprop': [[2, 3, 4], [1, 1, 1]],

  1481.         'skip': ['backward']}),

  1482.     ('HistogramSummary', {

  1483.         'block': HistogramSummaryNet(),

  1484.         'desc_inputs': [Tensor(np.array([1.1]).astype(np.float32)),

  1485.                         Tensor(np.array([1.2]).astype(np.float32))],

  1486.         'skip': ['backward']}),

  1487. 

  1488. ]

  1489. 

  1490. test_case_lists = [test_case_nn_ops, test_case_math_ops, test_case_array_ops, test_case_other_ops]

  1491. test_case = functools.reduce(lambda x, y: x + y, test_case_lists)

  1492. # use -k to select certain testcast

  1493. # pytest tests/python/ops/test_ops.py::test_backward -k LayerNorm

  1494. 

  1495. 

  1496. test_exec_case = test_case

  1497. 

  1498. test_backward_exec_case = filter(lambda x: 'skip' not in x[1] or

  1499.                                            'backward' not in x[1]['skip'], test_case)

  1500. 

  1501. 

  1502. @non_graph_engine

  1503. @mindspore_test(pipeline_for_compile_forward_ge_graph_for_case_by_case_config)

  1504. def test_exec():

  1505.     context.set_context(mode=context.GRAPH_MODE)

  1506.     return test_exec_case

  1507. 

  1508. 

  1509. @mindspore_test(pipeline_for_compile_grad_ge_graph_for_case_by_case_config)

  1510. def test_backward_exec():

  1511.     context.set_context(mode=context.GRAPH_MODE)

  1512.     return test_backward_exec_case

  1513. 

  1514. 

  1515. raise_set = [

  1516.     ('Cast_Error', {

  1517.         'block': (P.Cast(), {'exception': TypeError}),

  1518.         'desc_const': [mstype.int32],

  1519.         'desc_inputs': ['wrong input'],

  1520.         'desc_bprop': [Tensor(np.ones((2, 3, 3, 5)).astype(np.int32))]}),

  1521.     ('Maximum_Error', {

  1522.         'block': (P.Maximum(), {'exception': TypeError}),

  1523.         'desc_const': [(1, 2, 3)],

  1524.         'desc_inputs': [[2, 3, 3, 5]],

  1525.         'desc_bprop': [[2, 3, 3, 5]]}),

  1526.     ('Shape_error', {

  1527.         'block': (P.Shape(), {'exception': TypeError}),

  1528.         'desc_inputs': [(64, 1)],

  1529.         'desc_bprop': [[64]]}),

  1530.     ('Flatten_Error', {

  1531.         'block': (NetForFlatten0D(), {'exception': ValueError}),

  1532.         'desc_inputs': [Tensor(np.array(0).astype(np.int32))],

  1533.         'desc_bprop': [Tensor(np.array(0).astype(np.int32))]}),

  1534.     ('ScatterNdUpdate', {

  1535.         'block': (P.ScatterNdUpdate(), {'exception': TypeError}),

  1536.         'desc_inputs': (Tensor(np.ones((2, 3), np.float32)),

  1537.                         Tensor(np.ones((2, 2), np.float32)),

  1538.                         Tensor(np.ones((2,), np.float32))),

  1539.         'desc_bprop': [[2, 3]]}),

  1540.     ('Pack', {

  1541.         'block': (NetForPackInput(P.Pack()), {'exception': ValueError}),

  1542.         'desc_inputs': [[2, 2]],

  1543.         'desc_bprop': [[1, 2, 2]]}),

  1544.     ('PReLU', {

  1545.         'block': (P.PReLU(), {'exception': ValueError}),

  1546.         'desc_inputs': [[2], [1]],

  1547.         'desc_bprop': [[1]]}),

  1548. 

  1549. ]

  1550. 

  1551. 

  1552. @mindspore_test(pipeline_for_compile_forward_ge_graph_for_case_by_case_config_exception)

  1553. def test_check_exception():

  1554.     return raise_set

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