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mindspore/tests/ut/cpp/operator/composite_test.cc

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  1. /**

  2.  * Copyright 2020 Huawei Technologies Co., Ltd

  3.  *

  4.  * Licensed under the Apache License, Version 2.0 (the "License");

  5.  * you may not use this file except in compliance with the License.

  6.  * You may obtain a copy of the License at

  7.  *

  8.  * http://www.apache.org/licenses/LICENSE-2.0

  9.  *

  10.  * Unless required by applicable law or agreed to in writing, software

  11.  * distributed under the License is distributed on an "AS IS" BASIS,

  12.  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.

  13.  * See the License for the specific language governing permissions and

  14.  * limitations under the License.

  15.  */

  16. #include <memory>

  17. 

  18. #include "common/common_test.h"

  19. #include "ir/anf.h"

  20. #include "ir/value.h"

  21. #include "frontend/operator/composite/composite.h"

  22. #include "frontend/operator/ops.h"

  23. #include "pipeline/jit/static_analysis/prim.h"

  24. #include "abstract/abstract_function.h"

  25. #include "debug/trace.h"

  26. 

  27. namespace mindspore {

  28. using Shape = abstract::Shape;

  29. 

  30. using AbstractScalar = abstract::AbstractScalar;

  31. using AbstractScalarPtr = abstract::AbstractScalarPtr;

  32. 

  33. using AbstractSlice = abstract::AbstractSlice;

  34. using AbstractSlicePtr = abstract::AbstractSlicePtr;

  35. 

  36. using AbstractTuple = abstract::AbstractTuple;

  37. using AbstractTuplePtr = abstract::AbstractTuplePtr;

  38. 

  39. using AbstractTensor = abstract::AbstractTensor;

  40. using AbstractTensorPtr = abstract::AbstractTensorPtr;

  41. 

  42. using AbstractNone = abstract::AbstractNone;

  43. using AbstractAttribute = abstract::AbstractAttribute;

  44. using AnalysisEngine = abstract::AnalysisEngine;

  45. using AnalysisEnginePtr = abstract::AnalysisEnginePtr;

  46. 

  47. class TestComposite : public UT::Common {

  48.  public:

  49.   virtual void SetUp();

  50.   virtual void TearDown();

  51. 

  52.   AnalysisEnginePtr engine_;

  53. };

  54. 

  55. void TestComposite::SetUp() {

  56.   // init resource

  57.   std::shared_ptr<FuncGraphManager> graph_manager = MakeManager();

  58.   engine_ = std::make_shared<AnalysisEngine>(abstract::GetPrimEvaluatorConstructors(), graph_manager);

  59. }

  60. 

  61. void TestComposite::TearDown() {

  62.   // destroy resource

  63. }

  64. 

  65. class UTCompositeUtils {

  66.  public:

  67.   static AbstractTensorPtr ArrayInt32Of(std::initializer_list<int64_t> shp) {

  68.     auto ele = std::make_shared<AbstractScalar>(kAnyValue, kInt64);

  69.     return std::make_shared<AbstractTensor>(ele, std::make_shared<Shape>(shp));

  70.   }

  71.   static FuncGraphPtr MakeFuncGraph(const MetaFuncGraphPtr &metaFuncGraphPtr, size_t nparam) {

  72.     FuncGraphPtr func_graph = std::make_shared<FuncGraph>();

  73.     std::vector<AnfNodePtr> inputs;

  74.     inputs.push_back(NewValueNode(metaFuncGraphPtr));

  75.     for (size_t i = 0; i < nparam; i++) {

  76.       inputs.push_back(func_graph->add_parameter());

  77.     }

  78.     CNodePtr cnode_prim = func_graph->NewCNode(inputs);

  79.     inputs.clear();

  80.     inputs.push_back(NewValueNode(prim::kPrimReturn));

  81.     inputs.push_back(cnode_prim);

  82.     CNodePtr cnode_return = func_graph->NewCNode(inputs);

  83.     func_graph->set_return(cnode_return);

  84.     return func_graph;

  85.   }

  86. };

  87. 

  88. TEST_F(TestComposite, test_TupleSlice_arg_two_numbers) {

  89.   MetaFuncGraphPtr tupleSlicePtr = std::make_shared<prim::TupleSlice>("tuple_slice");

  90.   FuncGraphPtr tupleSliceGraphPtr = UTCompositeUtils::MakeFuncGraph(tupleSlicePtr, 3);

  91. 

  92.   AbstractBasePtrList eles;

  93.   auto tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  94.   size_t tuple_size = 6;

  95.   for (size_t i = 0; i < tuple_size; i++) {

  96.     eles.push_back(tensor);

  97.   }

  98.   auto tuple_tensor = std::make_shared<AbstractTuple>(eles);

  99.   auto start_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(1));

  100.   auto stop_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(5));

  101.   AbstractBasePtrList args_spec_list = {tuple_tensor, start_index, stop_index};

  102. 

  103.   try {

  104.     engine_->Run(tupleSliceGraphPtr, args_spec_list);

  105.     FAIL() << "Excepted exception :Args type is wrong";

  106.   } catch (std::runtime_error const &err) {

  107.     ASSERT_TRUE(std::string(err.what()).find("TupleSlice input args size should be 2, but got 3") != std::string::npos);

  108.   } catch (...) {

  109.     FAIL() << "Excepted exception :Args type is wrong";

  110.   }

  111. }

  112. 

  113. TEST_F(TestComposite, test_TupleSlice_arg_one_number) {

  114.   MetaFuncGraphPtr tupleSlicePtr = std::make_shared<prim::TupleSlice>("tuple_slice");

  115.   FuncGraphPtr tupleSliceGraphPtr = UTCompositeUtils::MakeFuncGraph(tupleSlicePtr, 2);

  116. 

  117.   AbstractBasePtrList eles;

  118.   auto tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  119.   size_t tuple_size = 6;

  120.   for (size_t i = 0; i < tuple_size; i++) {

  121.     eles.push_back(tensor);

  122.   }

  123.   auto tuple_tensor = std::make_shared<AbstractTuple>(eles);

  124.   auto start_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(1));

  125.   AbstractBasePtrList args_spec_list = {tuple_tensor, start_index};

  126. 

  127.   try {

  128.     trace::ClearTraceStack();

  129.     engine_->Run(tupleSliceGraphPtr, args_spec_list);

  130.     FAIL() << "Excepted exception: Args type is wrong";

  131.   } catch (pybind11::type_error const &err) {

  132.     ASSERT_TRUE(true);

  133.   } catch (std::runtime_error const &err) {

  134.     if (std::strstr(err.what(), "TypeError") != nullptr) {

  135.       ASSERT_TRUE(true);

  136.     } else {

  137.       FAIL() << "Excepted exception: Args type is wrong, message: " << err.what();

  138.     }

  139.   } catch (...) {

  140.     FAIL() << "Excepted exception: Args type is wrong";

  141.   }

  142. }

  143. 

  144. TEST_F(TestComposite, test_TupleSlice_arg_slice) {

  145.   std::shared_ptr<py::scoped_interpreter> env = parse::python_adapter::set_python_scoped();

  146.   MetaFuncGraphPtr tupleSlicePtr = std::make_shared<prim::TupleSlice>("tuple_slice");

  147.   FuncGraphPtr tupleSliceGraphPtr = UTCompositeUtils::MakeFuncGraph(tupleSlicePtr, 2);

  148. 

  149.   AbstractBasePtrList eles;

  150.   auto tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  151.   size_t tuple_size = 6;

  152.   for (size_t i = 0; i < tuple_size; i++) {

  153.     eles.push_back(tensor);

  154.   }

  155.   auto tuple_tensor = std::make_shared<AbstractTuple>(eles);

  156.   auto start_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(1));

  157.   auto stop_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(6));

  158.   auto step = std::make_shared<AbstractScalar>(static_cast<int64_t>(2));

  159.   auto slice = std::make_shared<AbstractSlice>(start_index, stop_index, step);

  160.   AbstractBasePtrList args_spec_list = {tuple_tensor, slice};

  161. 

  162.   AbstractTuplePtr ret = dyn_cast<AbstractTuple>(engine_->Run(tupleSliceGraphPtr, args_spec_list).inferred->abstract());

  163.   if (ret == nullptr) {

  164.     FAIL() << "Cast ret to abstract tuple failed.";

  165.   }

  166.   size_t real = ret->size();

  167.   size_t expect = 3;

  168.   ASSERT_EQ(real, expect);

  169. }

  170. 

  171. TEST_F(TestComposite, test_TupleSlice_arg_slice_step_none) {

  172.   MetaFuncGraphPtr tupleSlicePtr = std::make_shared<prim::TupleSlice>("tuple_slice");

  173.   FuncGraphPtr tupleSliceGraphPtr = UTCompositeUtils::MakeFuncGraph(tupleSlicePtr, 2);

  174. 

  175.   AbstractBasePtrList eles;

  176.   auto tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  177.   size_t tuple_size = 6;

  178.   for (size_t i = 0; i < tuple_size; i++) {

  179.     eles.push_back(tensor);

  180.   }

  181.   auto tuple_tensor = std::make_shared<AbstractTuple>(eles);

  182.   auto start_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(1));

  183.   auto stop_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(5));

  184.   auto step = std::make_shared<AbstractNone>();

  185.   auto slice = std::make_shared<AbstractSlice>(start_index, stop_index, step);

  186.   AbstractBasePtrList args_spec_list = {tuple_tensor, slice};

  187. 

  188.   AbstractTuplePtr ret = dyn_cast<AbstractTuple>(engine_->Run(tupleSliceGraphPtr, args_spec_list).inferred->abstract());

  189.   if (ret == nullptr) {

  190.     FAIL() << "Cast ret to abstract tuple failed.";

  191.   }

  192.   size_t real = ret->size();

  193.   size_t expect = 4;

  194.   ASSERT_EQ(real, expect);

  195. }

  196. 

  197. TEST_F(TestComposite, test_TupleSlice_arg_slice_step_negative) {

  198.   MetaFuncGraphPtr tupleSlicePtr = std::make_shared<prim::TupleSlice>("tuple_slice");

  199.   FuncGraphPtr tupleSliceGraphPtr = UTCompositeUtils::MakeFuncGraph(tupleSlicePtr, 2);

  200. 

  201.   AbstractBasePtrList eles;

  202.   auto tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  203.   size_t tuple_size = 6;

  204.   for (size_t i = 0; i < tuple_size; i++) {

  205.     eles.push_back(tensor);

  206.   }

  207.   auto tuple_tensor = std::make_shared<AbstractTuple>(eles);

  208.   auto start_index = std::make_shared<AbstractNone>();

  209.   auto stop_index = std::make_shared<AbstractNone>();

  210.   auto step = std::make_shared<AbstractScalar>(static_cast<int64_t>(-1));

  211.   auto slice = std::make_shared<AbstractSlice>(start_index, stop_index, step);

  212.   AbstractBasePtrList args_spec_list = {tuple_tensor, slice};

  213. 

  214.   AbstractTuplePtr ret = dyn_cast<AbstractTuple>(engine_->Run(tupleSliceGraphPtr, args_spec_list).inferred->abstract());

  215.   if (ret == nullptr) {

  216.     FAIL() << "Cast ret to abstract tuple failed.";

  217.   }

  218.   size_t real = ret->size();

  219.   size_t expect = 6;

  220.   ASSERT_EQ(real, expect);

  221. }

  222. 

  223. TEST_F(TestComposite, test_TupleSlice_arg_slice_step_positive) {

  224.   MetaFuncGraphPtr tupleSlicePtr = std::make_shared<prim::TupleSlice>("tuple_slice");

  225.   FuncGraphPtr tupleSliceGraphPtr = UTCompositeUtils::MakeFuncGraph(tupleSlicePtr, 2);

  226. 

  227.   AbstractBasePtrList eles;

  228.   auto tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  229.   size_t tuple_size = 6;

  230.   for (size_t i = 0; i < tuple_size; i++) {

  231.     eles.push_back(tensor);

  232.   }

  233.   auto tuple_tensor = std::make_shared<AbstractTuple>(eles);

  234.   auto start_index = std::make_shared<AbstractScalar>(static_cast<int64_t>(-2));

  235.   auto stop_index = std::make_shared<AbstractNone>();

  236.   auto step = std::make_shared<AbstractScalar>(static_cast<int64_t>(-1));

  237.   auto slice = std::make_shared<AbstractSlice>(start_index, stop_index, step);

  238.   AbstractBasePtrList args_spec_list = {tuple_tensor, slice};

  239. 

  240.   AbstractTuplePtr ret = dyn_cast<AbstractTuple>(engine_->Run(tupleSliceGraphPtr, args_spec_list).inferred->abstract());

  241.   if (ret == nullptr) {

  242.     FAIL() << "Cast ret to abstract tuple failed.";

  243.   }

  244.   size_t real = ret->size();

  245.   size_t expect = 5;

  246.   ASSERT_EQ(real, expect);

  247. }

  248. 

  249. TEST_F(TestComposite, test_UnpackCall_3args) {

  250.   MetaFuncGraphPtr unPackCallPtr = std::make_shared<prim::UnpackCall>("UnPackCall");

  251.   FuncGraphPtr unPackCallGraphPtr = UTCompositeUtils::MakeFuncGraph(unPackCallPtr, 3);

  252. 

  253.   auto fn_arg= std::make_shared<abstract::PrimitiveAbstractClosure>(prim::kPrimMakeTuple);

  254.   AbstractTensorPtr tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  255.   AbstractBasePtrList eles;

  256.   for (size_t i = 0; i < 6; i++) {

  257.     eles.push_back(tensor);

  258.   }

  259.   AbstractTuplePtr tensor_tuple = std::make_shared<AbstractTuple>(eles);

  260.   AbstractTensorPtr arr_x = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  261.   AbstractTensorPtr arr_y = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  262.   AbstractTensorPtr arr_z = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  263.   std::vector<AbstractAttribute> tensor_map{{"x", arr_x}, {"y", arr_y}, {"z", arr_z}};

  264.   abstract::AbstractDictionaryPtr tensor_dict = std::make_shared<abstract::AbstractDictionary>(tensor_map);

  265. 

  266.   AbstractBasePtrList args_spec_list = {fn_arg, tensor_tuple, tensor_dict};

  267.   AbstractTuplePtr ret = dyn_cast<AbstractTuple>(engine_->Run(unPackCallGraphPtr, args_spec_list).inferred->abstract());

  268.   if (ret == nullptr) {

  269.     FAIL() << "Cast ret to abstract tuple failed.";

  270.   }

  271.   size_t real = ret->size();

  272.   size_t expect = 9;

  273.   ASSERT_EQ(real, expect);

  274. }

  275. 

  276. TEST_F(TestComposite, test_UnpackCall_5args) {

  277.   MetaFuncGraphPtr unPackCallPtr = std::make_shared<prim::UnpackCall>("UnPackCall");

  278.   FuncGraphPtr unPackCallGraphPtr = UTCompositeUtils::MakeFuncGraph(unPackCallPtr, 5);

  279. 

  280.   auto fn_arg = std::make_shared<abstract::PrimitiveAbstractClosure>(prim::kPrimMakeTuple);

  281.   AbstractTensorPtr tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  282.   AbstractBasePtrList eles;

  283.   for (size_t i = 0; i < 6; i++) {

  284.     eles.push_back(tensor);

  285.   }

  286.   AbstractTuplePtr tensor_tuple = std::make_shared<AbstractTuple>(eles);

  287.   AbstractTensorPtr arr_x = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  288.   AbstractTensorPtr arr_y = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  289.   AbstractTensorPtr arr_z = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  290.   std::vector<AbstractAttribute> tensor_map{{"x", arr_x}, {"y", arr_y}, {"z", arr_z}};

  291.   abstract::AbstractDictionaryPtr tensor_dict = std::make_shared<abstract::AbstractDictionary>(tensor_map);

  292. 

  293.   AbstractBasePtrList args_spec_list = {fn_arg, tensor_dict, tensor_tuple, tensor_dict, tensor_tuple};

  294.   AbstractTuplePtr ret = dyn_cast<AbstractTuple>(engine_->Run(unPackCallGraphPtr, args_spec_list).inferred->abstract());

  295.   if (ret == nullptr) {

  296.     FAIL() << "Cast ret to abstract tuple failed.";

  297.   }

  298.   size_t real = ret->size();

  299.   size_t expect = 18;

  300.   ASSERT_EQ(real, expect);

  301. }

  302. 

  303. TEST_F(TestComposite, test_ZipOperation) {

  304.   MetaFuncGraphPtr zip_op = std::make_shared<prim::ZipOperation>("zip_op");

  305.   FuncGraphPtr zip_op_graph = UTCompositeUtils::MakeFuncGraph(zip_op, 1);

  306. 

  307.   AbstractBasePtrList eles;

  308.   auto tensor = UTCompositeUtils::ArrayInt32Of({2, 3, 4});

  309.   size_t tuple_size = 3;

  310.   for (size_t i = 0; i < tuple_size; i++) {

  311.     eles.push_back(tensor);

  312.   }

  313.   auto tuple = std::make_shared<AbstractTuple>(eles);

  314.   AbstractBasePtrList args_spec_list = {tuple};

  315. 

  316.   AbstractTuplePtr ret = dyn_cast<AbstractTuple>(engine_->Run(zip_op_graph, args_spec_list).inferred->abstract());

  317.   if (ret == nullptr) {

  318.     FAIL() << "Cast ret to abstract tuple failed.";

  319.   }

  320.   size_t real = ret->size();

  321.   size_t expect = 3;

  322.   ASSERT_EQ(real, expect);

  323. }

  324. }  // namespace mindspore