Optimize the compile performance in Parser, FG, Manager and Renormalize:

--- Remove the routine of handling isolated nodes in Renormalize. Add isolated nodes from Parser&Resolver. Modify isolated nodes handling in FG&Manager. Optimize the renormalize routines. Other optimizations.
4 years ago · 8b8c59f01e
--- a/mindspore/ccsrc/debug/anf_ir_utils.cc
+++ b/mindspore/ccsrc/debug/anf_ir_utils.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -610,24 +610,7 @@ void AnfExporter::OutputOrderList(std::ofstream &ofs, const FuncGraphPtr &func_g
  constexpr int width = 4;
  ofs << "# order:\n";
  int i = 1;
  auto &isolate_nodes = func_graph->isolate_nodes();
  for (auto &node : order_list) {
    bool is_isolate = (isolate_nodes.find(node) != isolate_nodes.end());
    const std::string isolate_str = (is_isolate ? " # isolate" : "");
    ofs << '#' << std::setw(width) << i << ": " << node->DebugString() << isolate_str << '\n';
    ++i;
  }
 }

 void AnfExporter::OutputIsolateNodes(std::ofstream &ofs, const FuncGraphPtr &func_graph) {
  auto &isolate_nodes = func_graph->isolate_nodes();
  if (isolate_nodes.empty()) {
    return;
  }
  constexpr int width = 4;
  ofs << "# isolate nodes:\n";
  int i = 1;
  for (auto &node : isolate_nodes) {
    ofs << '#' << std::setw(width) << i << ": " << node->DebugString() << '\n';
    ++i;
  }
@@ -670,7 +653,6 @@ void AnfExporter::ExportOneFuncGraph(std::ofstream &ofs, const FuncGraphPtr &fun
  ofs << "}\n";

  OutputOrderList(ofs, func_graph);
  OutputIsolateNodes(ofs, func_graph);
 }

 void AnfExporter::ExportFuncGraph(const std::string &filename, const FuncGraphPtr &func_graph) {
--- a/mindspore/ccsrc/debug/anf_ir_utils.h
+++ b/mindspore/ccsrc/debug/anf_ir_utils.h
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -98,7 +98,6 @@ class AnfExporter {
  void OutputStatementComment(std::ofstream &ofs, const CNodePtr &node);
  virtual void OutputCNodes(std::ofstream &ofs, const std::vector<AnfNodePtr> &nodes, const FuncGraphPtr &func_graph);
  void OutputOrderList(std::ofstream &ofs, const FuncGraphPtr &func_graph);
  void OutputIsolateNodes(std::ofstream &ofs, const FuncGraphPtr &func_graph);

  int param_index;
  OrderedSet<FuncGraphPtr> func_graph_set{};
--- a/mindspore/ccsrc/debug/trace.cc
+++ b/mindspore/ccsrc/debug/trace.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -36,7 +36,7 @@
 #include "utils/log_adapter.h"

 namespace mindspore {
 // namespace to support debug trace infomation
 // namespace to support debug trace information
 namespace trace {
 using abstract::AbstractBasePtr;
 using abstract::AnalysisContextPtr;
@@ -167,7 +167,7 @@ std::string AnalyzedFuncGraphExporter::GetNodeType(const AnfNodePtr &node) {

  MS_EXCEPTION_IF_NULL(engine_);
  auto cfg = engine_->MakeConfig(node, cur_ctx_);
  auto ret = engine_->cache().GetValue(cfg);
  auto ret = engine_->analysis_cache().GetValue(cfg);
  if (ret == nullptr) {
    return "Undefined";
  }
@@ -180,7 +180,7 @@ AbstractBasePtr AnalyzedFuncGraphExporter::GetNodeAbstract(const AnfNodePtr &nod
  }
  MS_EXCEPTION_IF_NULL(engine_);
  auto cfg = engine_->MakeConfig(node, cur_ctx_);
  auto ret = engine_->cache().GetValue(cfg);
  auto ret = engine_->analysis_cache().GetValue(cfg);
  return ret == nullptr ? nullptr : ret->abstract();
 }

@@ -439,7 +439,7 @@ void AnalyzedFuncGraphExporter::ExportFuncGraph(const std::string &filename,
  param_index = 1;
  auto tagged_func_graphs = CalcTaggedFuncGraphs();

  // first output graph on the analysis stack
  // 1. Output graph on the analysis stack
  for (const auto &node_cfg : node_cfgs) {
    auto ctx = node_cfg->context();
    if (engine_ == nullptr) {
@@ -448,7 +448,7 @@ void AnalyzedFuncGraphExporter::ExportFuncGraph(const std::string &filename,
    if (context_map_.insert({ctx, false}).second) {
      context_vec_.push_back(ctx);
    }
    // the graph has already been printed
    // If the graph has already been printed
    if (context_map_[ctx]) {
      continue;
    }
@@ -456,7 +456,7 @@ void AnalyzedFuncGraphExporter::ExportFuncGraph(const std::string &filename,

    auto fg = ctx->func_graph();

    // set current context
    // Set current context
    cur_ctx_ = ctx;
    tagged_cnodes_ = tagged_func_graphs[fg];
    ExportOneFuncGraph(ofs, fg);
@@ -465,10 +465,10 @@ void AnalyzedFuncGraphExporter::ExportFuncGraph(const std::string &filename,

  tagged_cnodes_.clear();

  // print seperator between function graphs on analyzed graph call stack and others
  // Print separator between function graphs on analyzed graph call stack and others
  ofs << "#===============================================================================\n\n\n";

  // second output other graphs
  // 2. Output other graphs
  size_t ctx_idx = 0;
  while (ctx_idx < context_vec_.size()) {
    auto ctx = context_vec_[ctx_idx++];
--- a/mindspore/ccsrc/frontend/optimizer/opt.cc
+++ b/mindspore/ccsrc/frontend/optimizer/opt.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -238,27 +238,6 @@ bool SubstitutionList::ApplySubstitutionToIR(const OptimizerPtr &optimizer, cons
  return changes;
 }

 bool SubstitutionList::ApplySubstitutionsToIRForIsolate(const OptimizerPtr &optimizer) const {
  const auto &manager = optimizer->manager();
  const auto &nodes = manager->isolate_nodes();
  bool changes = false;
  bool loop = true;
  while (loop) {
    loop = false;
    std::for_each(list_.cbegin(), list_.cend(), [&](const auto &substitution) {
      std::for_each(nodes.cbegin(), nodes.cend(), [&](const auto &node) {
        bool change = ApplySubstitutionToIR(optimizer, node, substitution);
        changes = changes || change;
        loop = loop || change;
      });
    });
    if (is_once_) {
      break;
    }
  }
  return changes;
 }

 bool SubstitutionList::ApplySubstitutionsToIR(const OptimizerPtr &optimizer, const FuncGraphPtr &func_graph) const {
  // Add for substitution status counting
  size_t space = 0;
@@ -336,18 +315,6 @@ bool SubstitutionList::operator()(const FuncGraphPtr &func_graph, const Optimize
  } else {
    changes = ApplySubstitutionsToIR(optimizer, func_graph);
  }

  bool has_isolate = !manager->isolate_nodes().empty();
  if (has_isolate) {
 #ifdef ENABLE_PROFILE
    double t = GetTime();
 #endif
    bool change = ApplySubstitutionsToIRForIsolate(optimizer);
    changes = changes || change;
 #ifdef ENABLE_PROFILE
    MsProfile::StatTime("opt.isolate.transform." + optimizer->name(), GetTime() - t);
 #endif
  }
  return changes;
 }
 }  // namespace opt
--- a/mindspore/ccsrc/frontend/optimizer/opt.h
+++ b/mindspore/ccsrc/frontend/optimizer/opt.h
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -73,7 +73,7 @@ class SubstitutionList {
  bool ApplyIRToSubstitutions(const OptimizerPtr &optimizer, const FuncGraphPtr &func_graph) const;
  bool ApplySubstitutionToIR(const OptimizerPtr &optimizer, const AnfNodePtr &node, const SubstitutionPtr &sub) const;
  bool ApplySubstitutionsToIR(const OptimizerPtr &optimizer, const FuncGraphPtr &func_graph) const;
  bool ApplySubstitutionsToIRForIsolate(const OptimizerPtr &optimizer) const;

  std::vector<SubstitutionPtr> list_;
  // a flag to mark this list of Substitution can only be executed only once
  bool is_once_;
--- a/mindspore/ccsrc/pipeline/jit/action.cc
+++ b/mindspore/ccsrc/pipeline/jit/action.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -163,7 +163,7 @@ bool CombineLikeGraphs(const ResourcePtr &res) {
    auto &graphs = it.second;
    MS_LOG(DEBUG) << "Start combine like graph:" << it.first << ", size:" << graphs.size();
    auto fg = graphs[0];
    FuncGraphPtrList func_graphs = {fg};
    FuncGraphVector func_graphs = {fg};
    ClonerPtr cloner = std::make_shared<Cloner>(func_graphs, false, false, true, std::make_shared<TraceCopy>(),
                                                std::make_shared<TraceCombileLikeGraphs>());
    cloner->Run();
--- a/mindspore/ccsrc/pipeline/jit/parse/function_block.cc
+++ b/mindspore/ccsrc/pipeline/jit/parse/function_block.cc
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -37,7 +37,7 @@ FunctionBlock::FunctionBlock(const Parser &parser) : parser_(parser) {

 void FunctionBlock::AddPrevBlock(const FunctionBlockPtr &block) { prev_blocks_.push_back(block.get()); }

 static bool CanBeIsolateNode(const std::string &var_name, const AnfNodePtr &node) {
 static bool CanBeIsolatedNode(const std::string &var_name, const AnfNodePtr &node) {
  auto cnode = dyn_cast<CNode>(node);
  if (cnode == nullptr || cnode->inputs().empty()) {
    // Not a valid cnode, can not be isolate node.
@@ -46,7 +46,7 @@ static bool CanBeIsolateNode(const std::string &var_name, const AnfNodePtr &node
  auto prim = GetValueNode<PrimitivePtr>(cnode->inputs().at(0));
  if (prim == nullptr) {
    // Not a primitive cnode, it may have side effects or not,
    // we add it as an isolate node if its name is not '_' or empty.
    // We add it as an isolate node if its name is not '_' or empty.
    // this means that code like:
    //    _ = func_call()
    // will be ignored even if func_call() has side effects.
@@ -58,7 +58,7 @@ static bool CanBeIsolateNode(const std::string &var_name, const AnfNodePtr &node
  return has_effects;
 }

 // write variable records the variable name to corresponding node
 // Write variable records the variable name to corresponding node
 void FunctionBlock::WriteVariable(const std::string &var_name, const AnfNodePtr &node) {
  MS_LOG(DEBUG) << func_graph_->ToString() << " write var " << var_name << " with node " << node->DebugString();
  auto [iter, is_new_name] = vars_.emplace(var_name, std::make_pair(node, false));
@@ -67,18 +67,24 @@ void FunctionBlock::WriteVariable(const std::string &var_name, const AnfNodePtr
    // add it as an isolate node. for example:
    //   a = print(x)
    //   a = print(y)
    // when we write variable 'a = print(y)',
    // When we write variable 'a = print(y)',
    // the cnode 'print(x)' should added as an isolate node.
    if (!iter->second.second && CanBeIsolateNode(var_name, iter->second.first)) {
      func_graph_->AddIsolateNode(iter->second.first);
    auto is_used = iter->second.second;
    auto hidden_node = iter->second.first;
    auto is_isolated = CanBeIsolatedNode(var_name, hidden_node);
    MS_LOG(INFO) << "Isolated node found(Hidden), hidden_node: " << hidden_node->DebugString(2) << " is hidden by "
                 << node->DebugString(2) << " with the same name, var_name: " << var_name
                 << ", is_isolated: " << is_isolated << ", !is_used: " << !is_used;
    if (!is_used && is_isolated) {
      AddIsolatedNode(hidden_node);
    }
    iter->second = std::make_pair(node, false);
  }
 }

 // read variable from predecessors
 // Read variable from predecessors
 AnfNodePtr FunctionBlock::ReadVariable(const std::string &var) {
  // get var node if it is found
  // Get var node if it is found
  auto found = vars_.find(var);
  if (found != vars_.end()) {
    auto &node = found->second.first;
@@ -91,7 +97,7 @@ AnfNodePtr FunctionBlock::ReadVariable(const std::string &var) {
    }
    return node;
  }
  // get var from predecessor block ,if can't get the make a resolve node to it
  // Get var from predecessor block ,if can't get the make a resolve node to it
  if (matured_) {
    // If only one predecessor block, read the definition of var from it.
    if (prev_blocks_.size() == 1) {
@@ -99,7 +105,7 @@ AnfNodePtr FunctionBlock::ReadVariable(const std::string &var) {
      MS_EXCEPTION_IF_NULL(block);
      return block->ReadVariable(var);
    } else if (prev_blocks_.empty()) {
      // get namespace and make Resolve
      // Get namespace and make Resolve
      auto it = var_to_resolve_.find(var);
      if (it != var_to_resolve_.end()) {
        return it->second;
@@ -181,7 +187,7 @@ AnfNodePtr FunctionBlock::MakeResolve(const NameSpacePtr &name_space, const Symb
  return node;
 }

 // add input for the block's phi parameter
 // Add input for the block's phi parameter
 void FunctionBlock::SetPhiArgument(const ParameterPtr &phi) {
  std::string var = phi_nodes_[phi];
  MS_LOG(DEBUG) << "graph " << func_graph_->ToString() << " set phi " << phi->ToString() << " for var " << var;
@@ -227,7 +233,7 @@ AnfNodePtr FunctionBlock::SearchReplaceNode(const std::string &var, const Parame
 }

 // Check if there is removable unnecessary phi node in this graph.
 // as per the FIRM TR 3.2, a phi node can be remove if:
 // As per the FIRM TR 3.2, a phi node can be remove if:
 // <Quote>
 //    If all arguments of a φ-function are the same value s or the φfunction itself,
 //    then we remove the φ-function and let all users directly uses. We call such a
@@ -255,7 +261,7 @@ bool FunctionBlock::CollectRemovablePhi(const ParameterPtr &phi) {
  if (arg_node != nullptr) {
    MS_LOG(DEBUG) << "graph " << func_graph_->ToString() << " phi " << phi->ToString() << " can be replaced with "
                  << arg_node->DebugString();
    // replace var with new one. This equal to statement in TR "v0 is immediately replaced by v1."
    // Replace var with new one. This equal to statement in TR "v0 is immediately replaced by v1."
    WriteVariable(var, arg_node);
    removable_phis_[phi] = arg_node;
    resolve_to_removable_phis_[arg_node] = phi;
@@ -326,6 +332,8 @@ void FunctionBlock::Jump(const FunctionBlockPtr &target_block, AnfNodePtr node)
  jumps_[target_block.get()] = jump;
  target_block->AddPrevBlock(shared_from_this());
  func_graph()->set_output(jump);
  // Attach all isolated nodes.
  AttachIsolatedNodesBeforeReturn();
 }

 // Perform a conditional jump using switch operation.
@@ -341,6 +349,8 @@ void FunctionBlock::ConditionalJump(AnfNodePtr condNode, const FunctionBlockPtr
                                   NewValueNode(false_block->func_graph())});
  CNodePtr switch_app_new = func_graph()->NewCNodeInOrder({switch_app});
  func_graph()->set_output(switch_app_new);
  // Attach all isolated nodes.
  AttachIsolatedNodesBeforeReturn();
 }

 // Create cnode for the assign statement like 'self.target = source'.
@@ -349,11 +359,12 @@ void FunctionBlock::SetStateAssign(const AnfNodePtr &target, const AnfNodePtr &s
  const std::string primitive_name("assign");
  const std::string module_name("mindspore.ops.functional");
  ValueNodePtr assign_op = NewValueNode(prim::GetPythonOps(primitive_name, module_name, true));
  auto assign = func_graph_->NewCNodeInOrder({assign_op, target, source});
  func_graph_->AddIsolateNode(assign);
  auto assign_node = func_graph_->NewCNodeInOrder({assign_op, target, source});
  MS_LOG(DEBUG) << "Isolated node found(Assign), assign_node: " << assign_node->DebugString(2);
  AddIsolatedNode(assign_node);
 }

 void FunctionBlock::FindIsolateVariables() {
 void FunctionBlock::FindIsolatedNodes() {
  //
  // Search isolate nodes from variables, for example,
  // variable 'a' is an isolate node in below code:
@@ -374,7 +385,7 @@ void FunctionBlock::FindIsolateVariables() {
      used.emplace(node);
    }
  }
  // Add isolate nodes which is unused var but not found in used set.
  // Add isolated nodes which is unused var but not found in used set.
  for (const auto &var : vars_) {
    auto &node = var.second.first;
    bool is_used = var.second.second;
@@ -382,11 +393,52 @@ void FunctionBlock::FindIsolateVariables() {
      continue;
    }
    auto &var_name = var.first;
    if (used.find(node) == used.end() && CanBeIsolateNode(var_name, node)) {
      func_graph_->AddIsolateNode(node);
    if (used.find(node) == used.end() && CanBeIsolatedNode(var_name, node)) {
      // We don't call AddIsolatedNode(node) anymore.
      // If need, to call FindIsolatedNodes() in appropriate place.
      MS_LOG(ERROR) << "Isolated node found(NoUse), node: " << node->DebugString(2) << ", var_name: " << var_name;
    }
  }
 }

 void FunctionBlock::AddIsolatedNode(const AnfNodePtr &target) { isolated_nodes_.add(target); }

 void FunctionBlock::AttachIsolatedNodesBeforeReturn() {
  if (isolated_nodes_.size() == 0) {
    return;
  }

  std::vector<AnfNodePtr> states;
  states.emplace_back(NewValueNode(prim::kPrimMakeTuple));
  for (auto &node : isolated_nodes_) {
    MS_LOG(DEBUG) << "Adding dependency, node: " << node->DebugString(2) << " in " << func_graph()->ToString();
    states.emplace_back(node);
  }

  AnfNodePtr state = nullptr;
  // If there are only make_tuple and another node in states(the states size is 2),
  // do not need to make_tuple, just use the node.
  if (states.size() == 2) {
    state = states[1];
  } else {
    state = func_graph()->NewCNode(states);
  }

  AnfNodePtr old_output = nullptr;
  auto return_node = func_graph()->get_return();
  if (return_node) {
    if (return_node->inputs().size() < 1) {
      MS_LOG(EXCEPTION) << "Length of inputs of output node is less than 2";
    }
    old_output = return_node->input(1);
  } else {
    old_output = NewValueNode(kNone);
  }
  AnfNodePtr stop_grad_node = func_graph()->NewCNode({NewValueNode(prim::kPrimStopGradient), state});
  AnfNodePtr depend_node = func_graph()->NewCNode({NewValueNode(prim::kPrimDepend), old_output, stop_grad_node});
  MS_LOG(INFO) << "Attached for side-effect nodes, depend_node: " << depend_node->DebugString()
               << ", state: " << state->DebugString(2);
  func_graph()->set_output(depend_node, true);
 }
 }  // namespace parse
 }  // namespace mindspore
--- a/mindspore/ccsrc/pipeline/jit/parse/function_block.h
+++ b/mindspore/ccsrc/pipeline/jit/parse/function_block.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -28,7 +28,7 @@
 #include <utility>
 #include "pipeline/jit/parse/parse_base.h"
 #include "utils/log_adapter.h"
 #include "utils/ordered_map.h"
 #include "utils/ordered_set.h"

 namespace mindspore {
 namespace parse {
@@ -71,46 +71,51 @@ class FunctionBlock : public std::enable_shared_from_this<FunctionBlock> {
  AnfNodePtr MakeResolveOperation(const std::string &value);
  AnfNodePtr MakeResolve(const std::shared_ptr<NameSpace> &name_space, const std::shared_ptr<Symbol> &resolve_symbol);
  const std::unordered_map<ParameterPtr, AnfNodePtr> &removable_phis() const { return removable_phis_; }
  void FindIsolateVariables();
  void FindIsolatedNodes();
  void AddIsolatedNode(const AnfNodePtr &target);
  void AttachIsolatedNodesBeforeReturn();

 private:
  // block graph
  // Block graph
  FuncGraphPtr func_graph_;

  // the block's parser
  // Block parser
  const Parser &parser_;

  // A block is matured if all its prev_blocks is processed
  bool matured_;

  // store the nest-level block
  // refer to comments in Parser::func_block_list_;
  // Store the nest-level block.
  // Refer to comments in Parser::func_block_list_;
  std::vector<FunctionBlock *> prev_blocks_;

  // store args and variable's node, use a bool flag to indicate if the variable is used.
  // Store args and variable's node, use a bool flag to indicate if the variable is used.
  std::map<std::string, std::pair<AnfNodePtr, bool>> vars_;

  // phi_nodes map the parameter node to variable, it can be resolved if the block's predecessors are processed
  // Map the parameter node to variable, it can be resolved if the block's predecessors are processed
  std::map<ParameterPtr, std::string> phi_nodes_;

  // jumps map the successor block and the function call that perform jump
  // refer to comments in Parser::func_block_list_ that how to break the cyclic reference
  // Jumps map the successor block and the function call that perform jump
  // Refer to comments in Parser::func_block_list_ that how to break the cyclic reference
  std::map<FunctionBlock *, CNodePtr> jumps_;

  // keeps all removable phis which will be removed in one pass.
  // Keep all removable phis which will be removed in one pass.
  std::unordered_map<ParameterPtr, AnfNodePtr> removable_phis_;

  // Keeps the map for the resolve node to the removable phi node.
  // Keep the map for the resolve node to the removable phi node.
  // For the case that ReadVariable returns a phi node although this phi node
  // generated in the prev block is identified as removable. The other blocks
  // should find this phi node.
  std::unordered_map<AnfNodePtr, ParameterPtr> resolve_to_removable_phis_;

  // hold declared global variables in function
  // Hold declared global variables in function
  std::set<std::string> global_vars_;

  // keeps the new made resolve symbol for the variable not found in vars_.
  // Keep new made resolve symbol for the variable not found in vars_.
  std::unordered_map<std::string, AnfNodePtr> var_to_resolve_;

  // Isolated nodes.
  OrderedSet<AnfNodePtr> isolated_nodes_;
 };

 }  // namespace parse
--- a/mindspore/ccsrc/pipeline/jit/parse/parse.cc
+++ b/mindspore/ccsrc/pipeline/jit/parse/parse.cc
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -70,7 +70,7 @@ TypePtr GetMixedPrecisionTargetType(const FuncGraphPtr &func_graph) {
  }
 }

 // if any mixed precision flag add a cast node after the parameter node.
 // If any mixed precision flag add a cast node after the parameter node.
 AnfNodePtr GetMixedPrecisionCastHelp(const FuncGraphPtr &func_graph, const AnfNodePtr &param) {
  TypePtr dst_type;
  if (func_graph->has_flag(GRAPH_FLAG_MIX_PRECISION_FP32)) {
@@ -145,16 +145,16 @@ void Parser::CleanParserResource() {
 AnfNodePtr AppendParameterObj(const FuncGraphPtr &func_graph, const py::object &obj) {
  MS_EXCEPTION_IF_NULL(func_graph);
  auto value = py::cast<tensor::MetaTensorPtr>(obj);
  // parameter object should not be none
  // Parameter object should not be none
  if (value == nullptr || !value->is_parameter()) {
    MS_LOG(EXCEPTION) << "Parameter error: because obj is not Parameter object.";
  }

  // get the parameter name from parameter object
  // Get the parameter name from parameter object
  auto param_name = value->param_info()->name();

  auto top_graph = func_graph;
  // if the parameter node has been created , return it
  // If the parameter node has been created , return it
  AnfNodePtr para_node = nullptr;
  for (auto param : top_graph->parameters()) {
    auto param_node = dyn_cast<Parameter>(param);
@@ -169,7 +169,7 @@ AnfNodePtr AppendParameterObj(const FuncGraphPtr &func_graph, const py::object &
    node->set_default_param(value);
    // set_abstract for parameter
    auto abs = value->ToAbstract();
    // boarden value
    // Boarden value
    abs = abs->Broaden();
    node->set_abstract(abs);
    para_node = node;
@@ -185,7 +185,7 @@ void UpdataParam(const FuncGraphPtr &top_graph, const py::object &cell) {
 }

 void CheckFuncReturn(const FuncGraphPtr &fn, const std::shared_ptr<ParseAst> &ast) {
  // check whether the functions referred by this function and itself are missing 'return' statement
  // Check whether the functions referred by this function and itself are missing 'return' statement
  auto mng = Manage(fn, false);
  for (auto func_graph : mng->func_graphs()) {
    if (func_graph->get_return() != nullptr) {
@@ -197,14 +197,14 @@ void CheckFuncReturn(const FuncGraphPtr &fn, const std::shared_ptr<ParseAst> &as
      python_adapter::CallPyModFn(ast->module(), PYTHON_MOD_GET_OBJECT_DESCRIPTION, ast->function(), ret[0], ret[1]);
    MS_EXCEPTION(TypeError) << "Missing return statement in " << desc.cast<std::string>() << ".";
  }
  // clear manager info after checking missing return
  // Clear manager info after checking missing return
  for (auto fg : mng->func_graphs()) {
    fg->ClearAllManagerInfo();
  }
 }

 FuncGraphPtr Parser::ParseFuncGraph() {
  // get ast FunctionDef node
  // Get ast FunctionDef node
  py::object node = ast_->GetAstNode();
  FunctionBlockPtr pFnBlock = ParseFunction(node);
  if (errcode() != PARSE_SUCCESS) {
@@ -214,7 +214,8 @@ FuncGraphPtr Parser::ParseFuncGraph() {

  // Add unused variables as isolate nodes.
  for (auto &block : func_block_list_) {
    block->FindIsolateVariables();
    // Find unused variables.
    block->FindIsolatedNodes();
  }

  RemoveUnnecessaryPhis();
@@ -294,7 +295,7 @@ ScopePtr Parser::GetScopeForParseFunction() {

 FunctionBlockPtr Parser::ParseFunction(const py::object &node, const FunctionBlockPtr &block) {
  ScopePtr scope = GetScopeForParseFunction();
  // the node created in the parsefunction context, will inherit the scope created using scope_guard
  // The node created in the parsefunction context, will inherit the scope created using scope_guard
  ScopeGuard scope_guard(scope);
  TraceGuard trace_guard(data_converter::GetObjKey(ast()->obj())[0], GetLocation(node));
  FunctionBlockPtr pFunBlock = MakeFunctionBlock(*this);
@@ -326,12 +327,12 @@ FunctionBlockPtr Parser::ParseFunction(const py::object &node, const FunctionBlo
  }
  GenerateArgsNodeForFunction(pFunBlock, node);

  // when parsing the top graph of construct, save the top graph
  // When parsing the top graph of construct, save the top graph
  if (GetTopFuncGraph() == nullptr) {
    UpdateTopFuncGraph(pFunBlock->func_graph());
  }

  // save the function node to block
  // Save the function node to block
  pFunBlock->WriteVariable(function_name, NewValueNode(current_fg));

  py::object funcObj = python_adapter::GetPyObjAttr(node, "body");
@@ -346,33 +347,35 @@ FunctionBlockPtr Parser::ParseFunction(const py::object &node, const FunctionBlo
  return pFunBlock;
 }

 FunctionBlockPtr Parser::ParseStatements(FunctionBlockPtr fn_block, const py::object &nodes) {
 FunctionBlockPtr Parser::ParseStatements(FunctionBlockPtr block, const py::object &nodes) {
  auto node_list = py::cast<py::list>(nodes);
  size_t count = py::len(node_list);
  MS_LOG(DEBUG) << "The nodes count is " << count;
  for (size_t i = 0; i < count; ++i) {
    auto node = node_list[i];
    fn_block = ParseStatement(fn_block, node);
    // insert appropriate depended items for the function block if it has a return node
    if (fn_block->func_graph()->get_return() != nullptr) {
    block = ParseStatement(block, node);
    // Insert appropriate depended items for the function block if it has a return node
    if (block->func_graph()->get_return() != nullptr) {
      // Attach all isolated nodes.
      block->AttachIsolatedNodesBeforeReturn();
      // Skip statements after 'return' (or 'break', 'continue').
      break;
    }
  }
  return fn_block;
  return block;
 }

 FunctionBlockPtr Parser::ParseStatement(const FunctionBlockPtr &block, const py::object &node) {
  TraceGuard trace_guard(GetLocation(node));
  auto node_type = ast_->GetNodeType(node);

  // check the node type
  // Check the node type
  AstMainType nodeType = node_type->main_type();
  if (nodeType != AST_MAIN_TYPE_STMT) {
    MS_LOG(INFO) << "Node type is error : " << nodeType;
    return block;
  }
  // call the process function
  // Call the process function
  std::string node_name = node_type->node_name();
  MS_LOG(DEBUG) << "Ast node is " << node_name;
  if (stmt_method_map_.count(node_name)) {
@@ -389,14 +392,14 @@ AnfNodePtr Parser::ParseExprNode(const FunctionBlockPtr &block, const py::object
  MS_LOG(DEBUG) << "Process ast expr";
  TraceGuard trace_guard(GetLocation(node));
  auto node_type = ast_->GetNodeType(node);
  // check the node type
  // Check the node type
  AstMainType node_main_type = node_type->main_type();
  if (node_main_type != AST_MAIN_TYPE_EXPR) {
    MS_LOG(ERROR) << "Node type is error : " << node_main_type;
    errcode_ = PARSE_NODE_TYPE_NO_MATCH;
    return nullptr;
  }
  // call the process function
  // Call the process function
  std::string node_name = node_type->node_name();
  MS_LOG(DEBUG) << "Ast node is " << node_name;
  if (expr_method_map_.count(node_name)) {
@@ -409,34 +412,37 @@ AnfNodePtr Parser::ParseExprNode(const FunctionBlockPtr &block, const py::object
  }
 }

 // process the expr statement and expand it
 // Process the expr statement and expand it
 FunctionBlockPtr Parser::ParseExpr(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Expr";
  // Expr only have value , no target
  // Expr only have value, no target
  py::tuple expand_info = ast_->CallParserObjMethod(PYTHON_PARSE_EXPAND_EXPR_STATEMENT, node);

  // refer python function expand_expr_statement, expand_info is one of the following:
  // Refer python function expand_expr_statement, expand_info is one of the following:
  // True, expr.value, x
  // True, expr.value
  // False, None, None
  // check the expand info result
  //
  // Check the expand info result
  auto is_expand = py::cast<bool>(expand_info[0]);
  if (is_expand) {
    // process the expr statement
    // Process the expr statement
    py::object value_object = expand_info[1];
    AnfNodePtr value_node = ParseExprNode(block, value_object);

    // Make a Expr CNode.
    AnfNodePtr call_node = ParseExprNode(block, value_object);
    if (py::len(expand_info) == 2) {
      // expression that not assigned to any variable,
      // this is usually a call with side effects,
      // Expression that not assigned to any variable.
      // This is usually a call with side effects.
      // e.g.: print(x)
      // we save it as an isolate node.
      value_node->func_graph()->AddIsolateNode(value_node);
      // We save it as an isolated node.
      auto &no_return_node = call_node;
      MS_LOG(INFO) << "Isolated node found(NoReturn), no_return_node: " << no_return_node->DebugString(2);
      block->AddIsolatedNode(no_return_node);
    } else {
      // expand the assign statement,
      // Expand the assign statement,
      // e.g.: x.append(y)  -> x = x.append(y)
      py::object target_node = expand_info[2];
      WriteAssignVars(block, target_node, value_node);
      WriteAssignVars(block, target_node, call_node);
    }
  }
  return block;
@@ -448,7 +454,7 @@ LocationPtr Parser::GetLocation(const py::object &node) const {
  if (ret.size() < 5) {
    MS_LOG(EXCEPTION) << "List size should not be less than 5.";
  }
  // refer to Location::Location() for each member of ret: line, column, line_end, column_end.
  // Refer to Location::Location() for each member of ret: line, column, line_end, column_end.
  auto location = std::make_shared<Location>(ret[0].cast<std::string>(), ret[1].cast<int64_t>(), ret[2].cast<int64_t>(),
                                             ret[3].cast<int64_t>(), ret[4].cast<int64_t>());
  return location;
@@ -466,9 +472,9 @@ void Parser::MakeConditionBlocks(const FunctionBlockPtr &pre_block, const Functi
 FunctionBlockPtr Parser::ParseReturn(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast return";
  MS_EXCEPTION_IF_NULL(block);
  // create return valuenode
  // Create return valuenode
  AnfNodePtr pReturnValueNode = NewValueNode(prim::kPrimReturn);
  // parse the return Statements value
  // Parse the return Statements value
  py::object value = python_adapter::GetPyObjAttr(node, "value");
  AnfNodePtr pReturnStatementNode = ParseExprNode(block, value);
  // Create the cnode
@@ -486,7 +492,7 @@ AnfNodePtr Parser::ParseBinOp(const FunctionBlockPtr &block, const py::object &n
  py::object left = python_adapter::GetPyObjAttr(node, "left");
  py::object right = python_adapter::GetPyObjAttr(node, "right");
  py::object op = python_adapter::GetPyObjAttr(node, "op");
  // create left and right ANF node
  // Create left and right ANF node
  AnfNodePtr left_node = ParseExprNode(block, left);
  if (left_node == nullptr) {
    MS_LOG(WARNING) << "DoBinOp process left node failed: " << errcode();
@@ -497,9 +503,9 @@ AnfNodePtr Parser::ParseBinOp(const FunctionBlockPtr &block, const py::object &n
    MS_LOG(WARNING) << "DoBinOp process right node failed:" << errcode();
    return nullptr;
  }
  // resolve the op
  // Resolve the op
  AnfNodePtr op_node = block->MakeResolveAstOp(op);
  // create apply node
  // Create apply node
  return block->func_graph()->NewCNodeInOrder({op_node, left_node, right_node});
 }

@@ -622,10 +628,10 @@ AnfNodePtr Parser::ParseSuper(const FunctionBlockPtr &block, const py::list &arg
  return block->MakeResolve(name_space, symbol);
 }

 // process function call, eg : f1(x, y) ...
 // Process function call, eg : f1(x, y) ...
 AnfNodePtr Parser::ParseCall(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Call";
  // process function call
  // Process function call
  py::object function_ast_node = python_adapter::GetPyObjAttr(node, "func");
  py::list args = python_adapter::GetPyObjAttr(node, "args");

@@ -639,13 +645,13 @@ AnfNodePtr Parser::ParseCall(const FunctionBlockPtr &block, const py::object &no
  }

  AnfNodePtr call_function_anf_node = ParseExprNode(block, function_ast_node);
  // function call arguments should be passed in as groups and unpacked later using unpack call
  // Function call arguments should be passed in as groups and unpacked later using unpack call
  std::vector<AnfNodePtr> packed_arguments;
  std::vector<AnfNodePtr> group_arguments;

  bool need_unpack_args = ParseArgsInCall(block, args, &packed_arguments, &group_arguments);
  bool need_unpack_keywords = ParseKeywordsInCall(block, node, &packed_arguments);
  // if there is stared or keyword argument, unpack may be needed
  // If there is stared or keyword argument, unpack may be needed
  bool need_unpack = need_unpack_args || need_unpack_keywords;

  return GenerateAnfNodeForCall(block, call_function_anf_node, packed_arguments, group_arguments, need_unpack);
@@ -666,7 +672,7 @@ CNodePtr MakeUnpackCall(const FuncGraphPtr &func_graph, const AnfNodePtr &call_f
 AnfNodePtr Parser::GenerateAnfNodeForCall(const FunctionBlockPtr &block, const AnfNodePtr &call_function_anf_node,
                                          const std::vector<AnfNodePtr> &packed_arguments,
                                          const std::vector<AnfNodePtr> &group_arguments, bool need_unpack) const {
  // if there is keyword arguments or starred, using an unpack_call op to unpack the argument
  // If there is keyword arguments or starred, using an unpack_call op to unpack the argument
  if (need_unpack) {
    return MakeUnpackCall(block->func_graph(), call_function_anf_node, packed_arguments);
  }
@@ -732,11 +738,11 @@ bool Parser::ParseKeywordsInCall(const FunctionBlockPtr &block, const py::object
  return need_unpack;
 }

 // process call attributes of class type define, eg: x.y()
 // Process call attributes of class type define, eg: x.y()
 AnfNodePtr Parser::ParseAttribute(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Attribute";

  // process class value,eg: self.xx
  // Process class value,eg: self.xx
  if (ast()->target_type() == PARSE_TARGET_OBJECT_INSTANCE) {
    if (ast_->IsClassMember(node)) {
      std::string var_name = "self.";
@@ -754,12 +760,12 @@ AnfNodePtr Parser::ParseAttribute(const FunctionBlockPtr &block, const py::objec
    }
  }

  // process the get attr
  // Use the Primitive replace the operation resolve node (getattr)
  // Process the get attr
  // Use the Primitive replace the operation resolve node (getattr),
  // because the getattr will eventually be converted to Primitive node
  AnfNodePtr op_node = NewValueNode(prim::kPrimGetAttr);

  // process the attr body
  // Process the attr body
  py::object value_body = python_adapter::GetPyObjAttr(node, "value");
  AnfNodePtr value_node = ParseExprNode(block, value_body);
  if (value_node == nullptr) {
@@ -767,7 +773,7 @@ AnfNodePtr Parser::ParseAttribute(const FunctionBlockPtr &block, const py::objec
    return nullptr;
  }

  // process the node attr
  // Process the node attr
  auto attr_str = python_adapter::GetPyObjAttr(node, "attr").cast<std::string>();
  MS_LOG(DEBUG) << "Attr = " << attr_str;
  AnfNodePtr attr_node = nullptr;
@@ -776,7 +782,7 @@ AnfNodePtr Parser::ParseAttribute(const FunctionBlockPtr &block, const py::objec
    attr_node = NewValueNode(attr_str);
  }

  // create the apply node
  // Create the apply node
  return block->func_graph()->NewCNodeInOrder({op_node, value_node, attr_node});
 }

@@ -784,8 +790,8 @@ AnfNodePtr Parser::ParseAttribute(const FunctionBlockPtr &block, const py::objec
 AnfNodePtr Parser::ParseCompare(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Compare";

  // for python comparison ,there may be if x>y>5 ,
  // which there is two ops , but we only support one now
  // For python comparison ,there may be if x>y>5 ,
  // Which there is two ops , but we only support one now
  py::list ops = python_adapter::GetPyObjAttr(node, "ops");
  if (ops.size() > MAX_COMPARISON_OPS_SUPPORTED) {
    MS_LOG(ERROR) << "MindSpore does not support comparison with operators more than one now, ops size =" << ops.size();
@@ -804,7 +810,7 @@ AnfNodePtr Parser::ParseCompare(const FunctionBlockPtr &block, const py::object
 }

 AnfNodePtr Parser::ProcessBoolOpValueList(const FunctionBlockPtr &block, const py::list &value_list, AstSubType mode) {
  // if there is only one bool op now
  // If there is only one bool op now
  if (value_list.size() == 1) {
    AnfNodePtr first_node = ParseExprNode(block, value_list[0]);
    return first_node;
@@ -828,8 +834,8 @@ AnfNodePtr Parser::ProcessBoolOpValueList(const FunctionBlockPtr &block, const p
    MakeConditionBlocks(block, true_block, false_block);
    FunctionBlockPtr b1, b2;

    // if it is and, we need to process the rest nodes;
    // if it is or, we continue to next
    // If it is and, we need to process the rest nodes;
    // If it is or, we continue to next
    if (mode == AST_SUB_TYPE_AND) {
      b1 = true_block;
      b2 = false_block;
@@ -875,7 +881,7 @@ FunctionBlockPtr Parser::ParseFunctionDef(const FunctionBlockPtr &block, const p
  FunctionBlockPtr function_block = ParseFunction(node, block);
  MS_EXCEPTION_IF_NULL(function_block);

  // get function name
  // Get function name
  py::str name = python_adapter::GetPyObjAttr(node, "name");
  std::string function_name = name;
  ValueNodePtr valuenode_graph = NewValueNode(function_block->func_graph());
@@ -890,7 +896,7 @@ AnfNodePtr Parser::ParseLambda(const FunctionBlockPtr &block, const py::object &
  func_block->AddPrevBlock(block);
  func_block->Mature();

  // get lambda args
  // Get lambda args
  py::list args = ast_->GetArgs(node);
  for (std::size_t i = 0; i < args.size(); i++) {
    std::string arg = py::cast<std::string>(args[i].attr("arg"));
@@ -909,7 +915,7 @@ AnfNodePtr Parser::ParseLambda(const FunctionBlockPtr &block, const py::object &
  return const_graph;
 }

 // process a tuple
 // Process a tuple
 AnfNodePtr Parser::ParseTuple(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Tuple";
  MS_EXCEPTION_IF_NULL(block);
@@ -930,7 +936,7 @@ AnfNodePtr Parser::ParseTuple(const FunctionBlockPtr &block, const py::object &n
  return tuple_app;
 }

 // process a list
 // Process a list
 AnfNodePtr Parser::ParseList(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast List";
  MS_EXCEPTION_IF_NULL(block);
@@ -951,7 +957,7 @@ AnfNodePtr Parser::ParseList(const FunctionBlockPtr &block, const py::object &no
  return list_app;
 }

 // process a subscript, such as x[y] , node expressed as value[slice]
 // Process a subscript, such as x[y] , node expressed as value[slice]
 AnfNodePtr Parser::ParseSubscript(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Subscript";
  MS_EXCEPTION_IF_NULL(block);
@@ -964,7 +970,7 @@ AnfNodePtr Parser::ParseSubscript(const FunctionBlockPtr &block, const py::objec
  return block->func_graph()->NewCNodeInOrder({op_getitem, value, slice});
 }

 // process a slice, get the slice value
 // Process a slice, get the slice value
 AnfNodePtr Parser::ParseSlice(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Slice";
  MS_EXCEPTION_IF_NULL(block);
@@ -979,7 +985,7 @@ AnfNodePtr Parser::ParseSlice(const FunctionBlockPtr &block, const py::object &n
  return block->func_graph()->NewCNodeInOrder({op_makeslice, start_node, stop_node, step_node});
 }

 // process a extslice
 // Process a extslice
 AnfNodePtr Parser::ParseExtSlice(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast ExtSlice";
  MS_EXCEPTION_IF_NULL(block);
@@ -996,20 +1002,20 @@ AnfNodePtr Parser::ParseExtSlice(const FunctionBlockPtr &block, const py::object
  return tuple_conde;
 }

 // process a index, get the index number
 // Process a index, get the index number
 AnfNodePtr Parser::ParseIndex(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Index";
  py::object value_node = python_adapter::GetPyObjAttr(node, "value");
  return ParseExprNode(block, value_node);
 }

 // process a  UnaryOp, +a, -b
 // Process a  UnaryOp, +a, -b
 AnfNodePtr Parser::ParseUnaryOp(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast UnaryOp";
  py::object op = python_adapter::GetPyObjAttr(node, "op");

  MS_EXCEPTION_IF_NULL(block);
  // resolve the op
  // Resolve the op
  AnfNodePtr op_node = block->MakeResolveAstOp(op);

  py::object operand = python_adapter::GetPyObjAttr(node, "operand");
@@ -1017,7 +1023,7 @@ AnfNodePtr Parser::ParseUnaryOp(const FunctionBlockPtr &block, const py::object
  return block->func_graph()->NewCNodeInOrder({op_node, operand_node});
 }

 // process a dict ast node expression
 // Process a dict ast node expression
 AnfNodePtr Parser::ParseDict(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Dict";
  py::list keys = node.attr("keys");
@@ -1035,7 +1041,7 @@ AnfNodePtr Parser::ParseDict(const FunctionBlockPtr &block, const py::object &no
  return block->func_graph()->NewCNodeInOrder({make_dict_op, keys_tuple, values_tuple});
 }

 // process a  augment assign such as a += b or mat[stride_slice] += b.
 // Process a  augment assign such as a += b or mat[stride_slice] += b.
 FunctionBlockPtr Parser::ParseAugAssign(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast AugAssign";
  MS_EXCEPTION_IF_NULL(block);
@@ -1065,7 +1071,7 @@ FunctionBlockPtr Parser::ParseAugAssign(const FunctionBlockPtr &block, const py:
  WriteAssignVars(block, target_obj, augassign_app);
  return block;
 }
 // process global declaration such as 'global x';
 // Process global declaration such as 'global x';
 FunctionBlockPtr Parser::ParseGlobal(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast Global";
  MS_EXCEPTION_IF_NULL(block);
@@ -1076,7 +1082,7 @@ FunctionBlockPtr Parser::ParseGlobal(const FunctionBlockPtr &block, const py::ob
  return block;
 }

 // process a if statement
 // Process a if statement
 FunctionBlockPtr Parser::ParseIf(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast If";
  py::object test_node = python_adapter::GetPyObjAttr(node, "test");
@@ -1104,25 +1110,25 @@ FunctionBlockPtr Parser::ParseIf(const FunctionBlockPtr &block, const py::object
  }

  if (MsContext::GetInstance()->backend_policy() != "ge") {
    // for backends excludes 'ge', it can handle multi graph call, use this flag to
    // For backends excludes 'ge', it can handle multi graph call, use this flag to
    // generate call not inline `after_block` graph to reduce if by if switch expansion.
    after_block->func_graph()->set_flag(FUNC_GRAPH_FLAG_AFTER_BLOCK, true);
  }

  // process the if-true branch
  // Process the if-true branch
  py::object bodyNode = python_adapter::GetPyObjAttr(node, "body");
  FunctionBlockPtr true_end = ParseStatements(true_block, bodyNode);

  // if the return_ is set ,it has its own continuation block
  // If the return_ is set ,it has its own continuation block
  if (true_end->func_graph()->get_return() == nullptr) {
    true_end->Jump(after_block, nullptr);
  }

  // process the orelse branch
  // Process the orelse branch
  py::object orelseNode = python_adapter::GetPyObjAttr(node, "orelse");
  FunctionBlockPtr false_end = ParseStatements(false_block, orelseNode);

  // if the return_ is set ,it has its own continuation block
  // If the return_ is set ,it has its own continuation block
  if (false_end->func_graph()->get_return() == nullptr) {
    false_end->Jump(after_block, nullptr);
  }
@@ -1220,7 +1226,7 @@ int64_t GetForTransToWhileLoop() {
 // A for loop will generate 3 functions :the test, the body, and the continuation
 // for x in xs:
 //    body
 // it is compiled to be following statement
 // It is compiled to be following statement
 // if len(xs) < max_loop_cnt:
 //    ParseForIter()  // use iter to implement for loop, which always unroll loop
 // else:
@@ -1228,7 +1234,7 @@ int64_t GetForTransToWhileLoop() {
 FunctionBlockPtr Parser::ParseFor(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast For, create an if else statement";
  MS_EXCEPTION_IF_NULL(block);
  // create statement 'len(xs) < MAX_FOR_LOOP_COUNT'
  // Create statement 'len(xs) < MAX_FOR_LOOP_COUNT'
  AnfNodePtr op_len = block->MakeResolveSymbol(NAMED_PRIMITIVE_LEN);
  py::object iter_obj = python_adapter::GetPyObjAttr(node, NAMED_PRIMITIVE_ITER);
  AnfNodePtr iter_node = ParseExprNode(block, iter_obj);
@@ -1236,7 +1242,7 @@ FunctionBlockPtr Parser::ParseFor(const FunctionBlockPtr &block, const py::objec
  CNodePtr bool_node = block->func_graph()->NewCNodeInOrder(
    {NewValueNode(prim::kPrimScalarLt), len_iter, NewValueNode(GetForTransToWhileLoop())});

  // create statement 'if len(xs) < prim::MAX_FOR_LOOP_COUNT then ParseForIter else ParseForLoop'
  // Create statement 'if len(xs) < prim::MAX_FOR_LOOP_COUNT then ParseForIter else ParseForLoop'
  FunctionBlockPtr true_block = nullptr;
  FunctionBlockPtr false_block = nullptr;
  {
@@ -1270,7 +1276,7 @@ FunctionBlockPtr Parser::ParseFor(const FunctionBlockPtr &block, const py::objec
 // A for loop will generate 3 functions :the test, the body, and the continuation
 // for x in xs:
 //    body
 // it is compiled to be following statement
 // It is compiled to be following statement
 // it = iter(xs)
 // while hastnext(it)
 //    x, it = next(it)
@@ -1282,21 +1288,21 @@ FunctionBlockPtr Parser::ParseForIter(const FunctionBlockPtr &block, const py::o
  AnfNodePtr op_next = block->MakeResolveOperation(NAMED_PRIMITIVE_NEXT);
  AnfNodePtr op_getitem = block->MakeResolveOperation(NAMED_PRIMITIVE_GETITEM);
  AnfNodePtr op_hasnext = block->MakeResolveOperation(NAMED_PRIMITIVE_HASNEXT);
  // generate the iterator apply
  // Generate the iterator apply
  CNodePtr iter_apply = GenerateIteratorInFor(block, node, op_iter);
  MS_EXCEPTION_IF_NULL(iter_apply);
  FunctionBlockPtr header_block =
    GenerateBlockInFor(std::make_shared<TraceForHeader>(block->func_graph()->debug_info()));
  MS_EXCEPTION_IF_NULL(header_block);
  // generate the hasnext apply which is a condition
  // Generate the hasnext apply which is a condition
  ParameterPtr iter_param = header_block->func_graph()->add_parameter();
  CNodePtr cond_apply = GenerateCondInFor(iter_param, header_block, op_hasnext);
  // generate the body of the for statement
  // Generate the body of the for statement
  FunctionBlockPtr body_block = GenerateBlockInFor(std::make_shared<TraceForBody>(block->func_graph()->debug_info()));
  MS_EXCEPTION_IF_NULL(body_block);
  body_block->AddPrevBlock(header_block);
  // generate the iterator next apply
  // process as following: `app = next(it); target = app[0]; it = app[1];`
  // Generate the iterator next apply
  // Process as following: `app = next(it); target = app[0]; it = app[1];`
  CNodePtr app = body_block->func_graph()->NewCNodeInOrder({op_next, iter_param});
  CNodePtr target_app =
    body_block->func_graph()->NewCNodeInOrder({op_getitem, app, NewValueNode(static_cast<int64_t>(0))});
@@ -1306,7 +1312,7 @@ FunctionBlockPtr Parser::ParseForIter(const FunctionBlockPtr &block, const py::o
    body_block->func_graph()->NewCNodeInOrder({op_getitem, app, NewValueNode(static_cast<int64_t>(1))});
  WriteAssignVars(body_block, target_node, target_app);

  // link the variable name with the target
  // Link the variable name with the target
  auto it_info = std::make_shared<TraceIterator>(target_app->debug_info());
  iter_param->debug_info()->set_trace_info(it_info);
  iter2_app->debug_info()->set_trace_info(it_info);
@@ -1348,7 +1354,7 @@ FunctionBlockPtr Parser::ParseForIter(const FunctionBlockPtr &block, const py::o
 // A for loop will generate 3 functions :the test, the body, and the continuation
 // for x in xs:
 //    body
 // it is compiled to be following statement
 // It is compiled to be following statement
 // i = 0
 // while i < len(xs)
 //    x = xs[i]
@@ -1360,10 +1366,10 @@ FunctionBlockPtr Parser::ParseForLoop(const FunctionBlockPtr &block, const py::o
  AnfNodePtr op_len = block->MakeResolveSymbol(NAMED_PRIMITIVE_LEN);
  AnfNodePtr op_getitem = block->MakeResolveOperation(NAMED_PRIMITIVE_GETITEM);

  // get variable name of 'x' in statement 'for x in xs'
  // Get variable name of 'x' in statement 'for x in xs'
  py::object target_node = python_adapter::GetPyObjAttr(node, "target");

  // create statement 'len(xs)'
  // Create statement 'len(xs)'
  py::object iter_obj = python_adapter::GetPyObjAttr(node, "iter");
  AnfNodePtr iter_node = ParseExprNode(block, iter_obj);
  MS_EXCEPTION_IF_NULL(iter_node);
@@ -1377,26 +1383,26 @@ FunctionBlockPtr Parser::ParseForLoop(const FunctionBlockPtr &block, const py::o
  FunctionBlockPtr header_block =
    GenerateBlockInFor(std::make_shared<TraceForHeader>(block->func_graph()->debug_info()));
  MS_EXCEPTION_IF_NULL(header_block);
  // create loop variable 'i'
  // Create loop variable 'i'
  ParameterPtr loop_var = header_block->func_graph()->add_parameter();
  // create loop condition 'i < len(xs)'
  // Create loop condition 'i < len(xs)'
  auto prim_less = prim::GetPythonOps("Less", "mindspore.ops.operations");
  auto less_node = header_block->func_graph()->NewCNodeInOrder({NewValueNode(prim_less)});
  CNodePtr cond_node = header_block->func_graph()->NewCNodeInOrder({less_node, loop_var, len_iter});

  // generate the body of the for statement
  // Generate the body of the for statement
  FunctionBlockPtr body_block = GenerateBlockInFor(std::make_shared<TraceForBody>(block->func_graph()->debug_info()));
  MS_EXCEPTION_IF_NULL(body_block);
  body_block->AddPrevBlock(header_block);
  // create 'x = xs[i]'
  // Create 'x = xs[i]'
  CNodePtr target_var = body_block->func_graph()->NewCNodeInOrder({op_getitem, iter_node, loop_var});
  WriteAssignVars(body_block, target_node, target_var);
  // create 'i = i + 1'
  // Create 'i = i + 1'
  CNodePtr loop_var_inc = body_block->func_graph()->NewCNodeInOrder(
    {NewValueNode(prim::kPrimScalarAdd), loop_var, NewValueNode(static_cast<int64_t>(1))});
  body_block->WriteVariable(loop_var->name(), loop_var_inc);

  // link the variable name with the target
  // Link the variable name with the target
  auto it_info = std::make_shared<TraceIterator>(loop_var_inc->debug_info());
  loop_var->debug_info()->set_trace_info(it_info);
  len_iter->debug_info()->set_trace_info(it_info);
@@ -1455,12 +1461,12 @@ AnfNodePtr Parser::ParseIfExp(const FunctionBlockPtr &block, const py::object &n

  MakeConditionBlocks(block, true_block, false_block);

  // process the if-true branch
  // Process the if-true branch
  py::object bodyNode = python_adapter::GetPyObjAttr(node, "body");
  true_block->func_graph()->debug_info()->set_location(GetLocation(bodyNode));
  AnfNodePtr true_node = ParseExprNode(true_block, bodyNode);

  // process the orelse branch
  // Process the orelse branch
  py::object orelseNode = python_adapter::GetPyObjAttr(node, "orelse");
  false_block->func_graph()->debug_info()->set_location(GetLocation(orelseNode));
  AnfNodePtr false_node = ParseExprNode(false_block, orelseNode);
@@ -1468,7 +1474,7 @@ AnfNodePtr Parser::ParseIfExp(const FunctionBlockPtr &block, const py::object &n
  true_block->func_graph()->set_output(true_node);
  false_block->func_graph()->set_output(false_node);

  // Use the Primitive replace the operation resolve node (switch)
  // Use the Primitive replace the operation resolve node (switch),
  // because the switch will eventually be converted to Primitive node
  CNodePtr switch_app = block->func_graph()->NewCNodeInOrder({NewValueNode(prim::kPrimSwitch), bool_node,
                                                              NewValueNode(true_block->func_graph()),
@@ -1485,9 +1491,9 @@ void Parser::HandleAssignName(const FunctionBlockPtr &block, const py::object &t
  py::str name = python_adapter::GetPyObjAttr(targ, "id");
  std::string name_id = name;
  assigned_node->debug_info()->set_name(name_id);
  // set the debug name of the constant graph
  // Set the debug name of the constant graph
  if (IsValueNode<FuncGraph>(assigned_node)) {
    // the value should be graph
    // The value should be graph
    auto fg = GetValueNode<FuncGraphPtr>(assigned_node);
    if (fg->debug_info()->name().empty()) {
      fg->debug_info()->set_name(name_id);
@@ -1501,7 +1507,7 @@ void Parser::HandleAssignTuple(const FunctionBlockPtr &block, const py::object &
  AnfNodePtr op_getitem = block->MakeResolveOperation(NAMED_PRIMITIVE_GETITEM);
  py::list items = python_adapter::GetPyObjAttr(targ, "elts");
  for (size_t i = 0; i < items.size(); i++) {
    // Use the Primitive replace the operation resolve node (getitem)
    // Use the Primitive replace the operation resolve node (getitem),
    // because the getitem will eventually be converted to Primitive node
    CNodePtr item_apply =
      block->func_graph()->NewCNodeInOrder({op_getitem, assigned_node, NewValueNode(static_cast<int64_t>(i))});
@@ -1546,7 +1552,7 @@ void Parser::HandleAssignSubscript(const FunctionBlockPtr &block, const py::obje
  AnfNodePtr value_node = ParseExprNode(block, value_obj);
  AnfNodePtr slice_node = ParseExprNode(block, slice_obj);
  CNodePtr setitem_app = block->func_graph()->NewCNodeInOrder({op_setitem, value_node, slice_node, assigned_node});
  // getitem apply should return the sequence data structure itself
  // Getitem apply should return the sequence data structure itself
  std::string var_name;
  if (ast_->IsClassMember(value_obj)) {
    std::string attr_name = value_obj.attr("attr").cast<std::string>();
@@ -1597,7 +1603,7 @@ void Parser::WriteAssignVars(const FunctionBlockPtr &block, const py::object &ta
  }
 }

 // process a assign statement, such as a =b,  a,b = tup
 // Process a assign statement, such as a =b,  a,b = tup
 FunctionBlockPtr Parser::ParseAssign(const FunctionBlockPtr &block, const py::object &node) {
  MS_LOG(DEBUG) << "Process ast assign";
  py::object value_object = python_adapter::GetPyObjAttr(node, "value");
@@ -1657,7 +1663,7 @@ AnfNodePtr FindPhis(const std::unordered_map<ParameterPtr, AnfNodePtr> &removabl
 }

 void Parser::RemoveUnnecessaryPhis() {
  // merge all removable phis to one map;
  // Merge all removable phis to one map;
  std::unordered_map<ParameterPtr, AnfNodePtr> removable_phis;
  std::vector<ParameterPtr> phis;
  for (FunctionBlockPtr &block : func_block_list_) {
@@ -1671,14 +1677,14 @@ void Parser::RemoveUnnecessaryPhis() {
  }
  auto fg_name = func_graph_->ToString();
  auto mng = Manage(func_graph_, false);
  // replace the nodes
  // remove from inside to outside
  // Replace the nodes
  // Remove from inside to outside
  for (int64_t idx = SizeToLong(phis.size() - 1); idx >= 0; idx--) {
    auto phi = phis[LongToSize(idx)];
    auto new_node = FindPhis(removable_phis, phi);
    mng->Replace(phi, new_node);
  }
  // remove the parameter
  // Remove the parameter
  for (FunctionBlockPtr &block : func_block_list_) {
    MS_EXCEPTION_IF_NULL(block);
    auto &local_removable_phis = block->removable_phis();
@@ -1693,7 +1699,7 @@ void Parser::RemoveUnnecessaryPhis() {
        return local_removable_phis.find(param->cast<ParameterPtr>()) == local_removable_phis.end();
      });

    // shrink container to new size
    // Shrink container to new size
    new_parameters.resize(std::distance(new_parameters.begin(), it));
    func_graph->set_parameters(new_parameters);
  }
@@ -1704,20 +1710,20 @@ void Parser::RemoveUnnecessaryPhis() {

 // ParseAst class code
 bool ParseAst::InitParseAstInfo(const std::string &python_mod_get_parse_method) {
  // init the type
  // Init the type
  target_type_ = PARSE_TARGET_UNKNOW;

  // call python parse, get the parser fn
  // Call python parse, get the parser fn
  module_ = python_adapter::GetPyModule(PYTHON_MOD_PARSE_MODULE);
  py::object parse_method = python_adapter::GetPyObjAttr(obj_, PYTHON_EXTERN_PARSE_METHOD);

  // get the obj type
  // Get the obj type
  auto type = data_converter::GetObjType(obj_);
  if (type == RESOLVE_TYPE_FUNCTION) {
    target_type_ = PARSE_TARGET_FUNCTION;
    function_ = obj_;
  } else if (type == RESOLVE_TYPE_METHOD) {
    // process the method ,need get the method's self obj
    // Process the method ,need get the method's self obj
    target_type_ = PARSE_TARGET_METHOD;
    py::object method_object = python_adapter::GetPyObjAttr(obj_, PYTHON_GET_METHOD_SELF_CLASS);
    if (py::isinstance<py::none>(method_object)) {
@@ -1735,7 +1741,7 @@ bool ParseAst::InitParseAstInfo(const std::string &python_mod_get_parse_method)
      return false;
    }
    target_type_ = PARSE_TARGET_OBJECT_INSTANCE;
    // check the fn is method
    // Check the fn is method
    auto obj_type = data_converter::GetObjType(function_);
    if (obj_type != RESOLVE_TYPE_METHOD) {
      MS_LOG(WARNING) << "Parse method function is invalid.";
@@ -1746,11 +1752,11 @@ bool ParseAst::InitParseAstInfo(const std::string &python_mod_get_parse_method)
    return false;
  }

  // call python parse get ast tree
  // Call python parse get ast tree
  parser_ = python_adapter::CallPyModFn(module_, PYTHON_MOD_PARSE_OBJECT_FUNCTION, function_, parse_method);
  ast_tree_ = python_adapter::CallPyObjMethod(parser_, "parse");

  // get fn name and module
  // Get fn name and module
  function_module_ = py::cast<std::string>(python_adapter::GetPyObjAttr(parser_, "function_module"));
  function_name_ = py::cast<std::string>(python_adapter::GetPyObjAttr(parser_, "function_name"));
  function_filename_ = py::cast<std::string>(python_adapter::GetPyObjAttr(parser_, "filename"));
@@ -1901,7 +1907,7 @@ FuncGraphPtr MakeTopGraph(const py::object &cell, const ValuePtr &cell_ptr) {
  // cell_obj
  MS_LOG(DEBUG) << "add Flag for " << std::string(py::str(cell));
  parse::UpdateFuncGraphFlags(cell, func_graph);
  // top graph's construct flag
  // Top graph's construct flag
  if (py::hasattr(cell, "construct")) {
    parse::UpdateFuncGraphFlags(cell.attr("construct"), func_graph);
  }
@@ -1917,7 +1923,7 @@ FuncGraphPtr MakeTopGraph(const py::object &cell, const ValuePtr &cell_ptr) {
  } else {
    // ret = cell_obj(*arg, *kwargs)
    auto call_fn = MakeUnpackCall(func_graph, NewValueNode(cell_ptr), func_graph->parameters());
    // return ret
    // Set output as ret
    func_graph->set_output(call_fn);
  }
  return func_graph;
--- a/mindspore/ccsrc/pipeline/jit/parse/resolve.cc
+++ b/mindspore/ccsrc/pipeline/jit/parse/resolve.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -197,7 +197,7 @@ AnfNodePtr TransformToMakeTupleNodes(const FuncGraphManagerPtr &manager, const F
  return cnode;
 }

 // transform the ValueTuple or ValueList of graph/primitive node to make tuple of const graph/primitive node
 // Transform the ValueTuple or ValueList of graph/primitive node to make tuple of const graph/primitive node
 bool TransformVectorFuncValueNode(const FuncGraphManagerPtr &manager, const FuncGraphPtr &func_graph,
                                  const ValueNodePtr &value_node, AnfNodePtr *const transformed) {
  MS_EXCEPTION_IF_NULL(value_node);
@@ -208,18 +208,18 @@ bool TransformVectorFuncValueNode(const FuncGraphManagerPtr &manager, const Func

  // (1) The celllist or ordered_cell will be parsed as valuetuple of const graph in it,
  // So if has graph in list, try to replace the node with make tuple of graph value node.
  // we do this because the graph manager won't investigate the graph inside valuetuple,
  // We do this because the graph manager won't investigate the graph inside valuetuple,
  // change the vector of graph to be make_tuple of graph value node.
  // (2) the primitive valuetuple or valuelist may encounter to abstract error, make it all
  // independent nodes.
  auto node_tuple_graphs = TransformToMakeTupleNodes(manager, func_graph, value_vec);
  // replace the ret ptr to be make tuple of graph value node
  // Replace the ret ptr to be make tuple of graph value node
  *transformed = node_tuple_graphs;

  return true;
 }

 // resolve the python obj, and if the resovled node is valuenode with graphs, add the graphs to manager
 // Resolve the python obj, and if the resovled node is valuenode with graphs, add the graphs to manager.
 AnfNodePtr ResolveObjectAndAddToManager(const FuncGraphManagerPtr &manager, const py::object &obj,
                                        const AnfNodePtr &node) {
  ScopeGuard scope_guard(node->scope());
@@ -233,7 +233,7 @@ AnfNodePtr ResolveObjectAndAddToManager(const FuncGraphManagerPtr &manager, cons
    manager->AddFuncGraph(new_fg);
  }

  // if the constant node is constant of vector of graph ,add graph to manager
  // If the constant node is constant of vector of graph, add graph to manager.
  if (IsValueNode<ValueTuple>(resolved_node) || IsValueNode<ValueList>(resolved_node)) {
    (void)TransformVectorFuncValueNode(manager, node->func_graph(), resolved_node->cast<ValueNodePtr>(),
                                       &resolved_node);
--- a/mindspore/ccsrc/pipeline/jit/pass.cc
+++ b/mindspore/ccsrc/pipeline/jit/pass.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -426,16 +426,6 @@ bool AddCacheEmbeddingPass(const ResourcePtr &res) {
  return true;
 }

 bool MergeDupGraphPass(const ResourcePtr &res) {
  FuncGraphPtr func_graph = res->func_graph();
  MS_EXCEPTION_IF_NULL(func_graph);
  MS_EXCEPTION_IF_NULL(res->manager());
  if (res->manager()->func_graphs().size() <= 1) {
    return true;
  }
  return MergeDuplicateGraphs(res->manager());
 }

 bool RemoveValueNodeDuplicationsPass(const ResourcePtr &res) {
  if (res->func_graph() == nullptr) {
    MS_LOG(EXCEPTION) << "Remove value node duplications error.";
--- a/mindspore/ccsrc/pipeline/jit/remove_value_node_dup.cc
+++ b/mindspore/ccsrc/pipeline/jit/remove_value_node_dup.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -73,107 +73,5 @@ void TryToDoReplace(FuncGraphManager *const manager, const AnfNodePtr &node, Has
  // Meet for the first time, append node to bucket.
  bucket.emplace_back(node);
 }

 size_t HashOfGraph(const FuncGraphPtr &fg) {
  std::vector<AnfNodePtr> toposet = TopoSort(fg->get_return());
  MS_LOG(DEBUG) << "TopSort for:" << fg->ToString();
  std::unordered_map<AnfNodePtr, std::size_t> hashes;
  auto &params = fg->parameters();
  for (size_t i = 0; i < params.size(); i++) {
    hashes[params[i]] = std::hash<std::string>{}("param" + std::to_string(i));
  }
  for (auto node : toposet) {
    MS_EXCEPTION_IF_NULL(node);
    if (hashes.find(node) != hashes.end()) {
      continue;
    }

    std::size_t h = 0;
    if (node->isa<ValueNode>()) {
      ValueNodePtr value_node = node->cast<ValueNodePtr>();
      auto value = value_node->value();
      MS_EXCEPTION_IF_NULL(value);
      if (IsValueNode<FuncGraph>(value_node)) {
        auto v_fg = value->cast<FuncGraphPtr>();
        h = value->hash();
      } else if (IsValueNode<tensor::Tensor>(value_node)) {
        // the tensor has same value has been replaced in duplicate value pass,
        // so we use the value pointer here as an identifier
        h = hash_combine(value->hash(), std::hash<Value *>{}(value.get()));
      } else {
        h = hash_combine(value->hash(), (opt::AbsOf(value_node)->hash()));
      }
    } else if (node->isa<CNode>()) {
      auto cnode = node->cast<CNodePtr>();
      auto &inputs = cnode->inputs();
      size_t init = 0;
      h = std::accumulate(inputs.begin(), inputs.end(), init, [&hashes](std::size_t hash, const AnfNodePtr &node_in) {
        return hash_combine(hash, hashes[node_in]);
      });
    } else if (node->isa<Parameter>()) {
      h = node->hash();
    } else {
      MS_LOG(ERROR) << "Unknow node type";
    }
    hashes[node] = h;
  }
  return hashes[fg->get_return()];
 }

 bool IsCNodeGraph(const AnfNodePtr &node) {
  if (node == nullptr || !node->isa<CNode>()) {
    return false;
  }

  auto inp0 = node->cast<CNodePtr>()->input(0);
  return IsValueNode<FuncGraph>(inp0);
 }

 bool MergeDuplicateGraphs(const FuncGraphManagerPtr manager) {
  std::unordered_map<size_t, std::vector<FuncGraphPtr>> hash_graphs;
  std::unordered_map<FuncGraphPtr, size_t> graph_hash;
  for (auto fg : manager->func_graphs()) {
    size_t h = HashOfGraph(fg);
    graph_hash[fg] = h;
    if (hash_graphs.find(h) == hash_graphs.end()) {
      hash_graphs[h] = {fg};
    } else {
      hash_graphs[h].push_back(fg);
    }
  }
  FuncGraphPairMapEquiv equiv_graph;
  NodeMapEquiv equiv_node;
  for (auto &fg : manager->func_graphs()) {
    MS_LOG(DEBUG) << "Try Merge Graph:" << fg->ToString();
    for (auto &item : fg->nodes()) {
      if (!item->isa<CNode>()) {
        continue;
      }
      auto &inputs = item->cast<CNodePtr>()->inputs();
      for (size_t i = 0; i < inputs.size(); i++) {
        if (!inputs[i]->isa<ValueNode>()) {
          continue;
        }
        auto value_ptr = GetValueNode(inputs[i]);
        auto v_fg = value_ptr->cast<FuncGraphPtr>();
        if (v_fg == nullptr) {
          continue;
        }
        auto &fg_vec = hash_graphs[graph_hash[v_fg]];
        if (fg_vec.size() > 1) {
          if (v_fg != fg_vec[0]) {
            bool is_morphic = Isomorphic(v_fg, fg_vec[0], &equiv_graph, &equiv_node);
            if (is_morphic) {
              auto new_node = NewValueNode(fg_vec[0]);
              MS_LOG(DEBUG) << "Replace graph node :" << inputs[i]->ToString() << " with:" << new_node->ToString();
              manager->Replace(inputs[i], new_node);
            }
          }
        }
      }
    }
  }
  return true;
 }
 }  // namespace pipeline
 }  // namespace mindspore
--- a/mindspore/ccsrc/pipeline/jit/remove_value_node_dup.h
+++ b/mindspore/ccsrc/pipeline/jit/remove_value_node_dup.h
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -28,9 +28,6 @@ using HashCache = std::unordered_map<std::size_t, std::vector<AnfNodePtr>>;
 using HashValue = std::unordered_map<AnfNodePtr, std::size_t>;

 void TryToDoReplace(FuncGraphManager *manager, const AnfNodePtr &node, HashCache *hash_cache, HashValue *hash_value);
 size_t HashOfGraph(const FuncGraphPtr &fg);
 bool IsCNodeGraph(const AnfNodePtr &node);
 bool MergeDuplicateGraphs(const FuncGraphManagerPtr manager);
 }  // namespace pipeline
 }  // namespace mindspore

--- a/mindspore/ccsrc/pipeline/jit/static_analysis/auto_monad.cc
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/auto_monad.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2020 Huawei Technologies Co., Ltd
 * Copyright 2020-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -846,7 +846,7 @@ class SideEffectFinder {
  const SccPtr &GetScc(const FuncGraphPtr &func_graph) const {
    auto found = scc_map_.find(func_graph);
    if (found == scc_map_.end()) {
      MS_LOG(EXCEPTION) << "SCC not found for " << func_graph->ToString();
      MS_LOG(EXCEPTION) << "SCC not found for " << func_graph->ToString() << "." << func_graph->debug_info()->get_id();
    }
    return found->second;
  }
@@ -1014,7 +1014,6 @@ class AutoMonadConverter {
      HandleCNodes();
    }
    // Clean up after conversion finished.
    func_graph_->ClearIsolateNodes();
    func_graph_->ClearOrderList();
    return has_effect_cnodes_;
  }
@@ -1248,9 +1247,17 @@ class AutoMonadConverter {
  }

  void InsertStateDepend(const AnfNodePtr &state) {
    auto output = GetGraphOutput();
    // It's safe to handle isolated nodes here:
    //   Node: Depend(output, StopGrad)
    if (IsPrimitiveCNode(output, prim::kPrimDepend) &&
        IsPrimitiveCNode(output->cast<CNodePtr>()->input(2), prim::kPrimStopGradient)) {
      // Replace Depend(orig_output, StopGrad) node with orig_output.
      // After that, nodes may be eliminated if have no side effects.
      output = output->cast<CNodePtr>()->input(1);
    }
    // Insert Depend node and set it as output.
    auto depend = NewValueNode(prim::kPrimDepend);
    auto output = GetGraphOutput();
    auto depend_cnode = func_graph_->NewCNode({depend, output, state});
    depend_cnode->set_abstract(output->abstract());
    func_graph_->set_output(depend_cnode);
@@ -1374,12 +1381,6 @@ bool AutoMonad(const FuncGraphPtr &func_graph) {
    bool fg_has_effects = AutoMonadConverter::Handle(fg, top_flag);
    has_effects = has_effects || fg_has_effects;
  }

  // Clear isolate nodes after auto-monad finished.
  auto manager = func_graph->manager();
  if (manager) {
    manager->ClearIsolateNodes();
  }
  return has_effects;
 }

@@ -1406,7 +1407,6 @@ bool ReAutoMonad(const FuncGraphPtr &func_graph) {
    for (auto &fg : func_graph->func_graphs_used_total()) {
      if (!fg->has_flag(mindspore::kFuncGraphFlagReAutoMonad)) {
        fg->ClearOrderList();
        fg->ClearIsolateNodes();
      }
    }
    changed = AutoMonad(func_graph);
@@ -1416,13 +1416,9 @@ bool ReAutoMonad(const FuncGraphPtr &func_graph) {
    // After auto monad, Order List and Isolate nodes in graph and manager will be cleared.
  } else {
    func_graph->ClearOrderList();
    func_graph->ClearIsolateNodes();
    for (auto &fg : func_graph->func_graphs_used_total()) {
      fg->ClearOrderList();
      fg->ClearIsolateNodes();
    }
    MS_EXCEPTION_IF_NULL(func_graph->manager());
    func_graph->manager()->ClearIsolateNodes();
  }
  return changed;
 }
--- a/mindspore/ccsrc/pipeline/jit/static_analysis/evaluator.cc
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/evaluator.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -83,11 +83,11 @@ EvalResultPtr BaseFuncGraphEvaluator::Eval(AnalysisEnginePtr engine, const Abstr
    const auto &arg = args_spec_list[i];
    const auto &node = parameters[i];
    AnfNodeConfigPtr conf = engine->MakeConfig(node, graph_context_);
    engine->cache().set_value(conf, std::make_shared<EvalResult>(arg, nullptr));
    engine->analysis_cache().set_value(conf, std::make_shared<EvalResult>(arg, nullptr));
  }
  const AnfNodePtr &func_node = fg->get_return();

  MS_LOG(DEBUG) << "Analysis FuncGraph begin, func graph: " << fg.get() << fg->ToString()
  MS_LOG(DEBUG) << "Analysis FuncGraph begin, func graph: " << fg << "/" << fg->ToString()
                << ", context: " << graph_context_->ToString() << ", return node: " << func_node->DebugString()
                << ", current function call depth: " << engine->function_call_depth();
  AbstractBasePtr ret_base = nullptr;
@@ -97,37 +97,20 @@ EvalResultPtr BaseFuncGraphEvaluator::Eval(AnalysisEnginePtr engine, const Abstr
                      << MsContext::GetInstance()->get_param<uint32_t>(MS_CTX_MAX_CALL_DEPTH)
                      << ", please call 'context.set_context(max_call_depth=value)' to adjust this value.";
  }
  // Analysis for isolate nodes first, as some validation check in FuncGraph is isolate nodes;
  for (const auto &node : fg->GetIsolateNodesInOrder()) {
    AnfNodeConfigPtr node_conf = engine->MakeConfig(node, graph_context_);
    MS_LOG(DEBUG) << "Analysis isolate_node begin, func graph: " << fg.get() << fg->ToString()
                  << ", node_conf: " << node_conf->ToString();
    auto isolate_base = engine->GetEvaluatedValue(node_conf)->abstract();
    MS_LOG(DEBUG) << "Analysis isolate_node end, func graph: " << fg.get() << fg->ToString()
                  << ", node_conf: " << node_conf->ToString() << ", abstract: " << isolate_base->ToString();
  }

  const auto &all_nodes = TopoSort(func_node, SuccIncoming, [&fg](const AnfNodePtr &node) -> IncludeType {
    if (node->func_graph() != fg || node->isa<ValueNode>()) {
      return EXCLUDE;
    }
    return FOLLOW;
  });
  bool isolate_node_propagate_flag = false;
  for (const auto &node : all_nodes) {
    AnfNodeConfigPtr node_conf = engine->MakeConfig(node, graph_context_);
    MS_LOG(DEBUG) << "Analysis node begin, func graph: " << fg.get() << fg->ToString()
    MS_LOG(DEBUG) << "Analysis node begin, func graph: " << fg << "/" << fg->ToString()
                  << ", node_conf: " << node_conf->ToString();
    auto node_eval_result = engine->GetEvaluatedValue(node_conf);
    auto node_eval_result = engine->ObtainEvalResultWithCache(node_conf);
    ret_base = node_eval_result->abstract();
    MS_LOG(DEBUG) << "Analysis node end, func graph: " << fg.get() << fg->ToString()
    MS_LOG(DEBUG) << "Analysis node end, func graph: " << fg << "/" << fg->ToString()
                  << ", node_conf: " << node_conf->ToString() << ", abstract: " << ret_base->ToString();
    if (node->isa<CNode>()) {
      isolate_node_propagate_flag |= node_eval_result->HasIsolateNodesPropagateCNodeFlag();
      MS_LOG(DEBUG) << "Check isolate_nodes flag for node: " << node->DebugString()
                    << ", abstract: " << ret_base->ToString()
                    << ", flag: " << node_eval_result->HasIsolateNodesPropagateCNodeFlag();
    }
  }
  engine->DecreaseFunctionCallDepth();

@@ -138,12 +121,7 @@ EvalResultPtr BaseFuncGraphEvaluator::Eval(AnalysisEnginePtr engine, const Abstr
  if (fg->stub()) {
    ret_base = std::make_shared<AbstractUndetermined>();
  }
  auto eval_result = std::make_shared<EvalResult>(ret_base, std::make_shared<AttrValueMap>());
  if (isolate_node_propagate_flag) {
    eval_result->SetIsolateNodesPropagateCNodeFlag(true);
    eval_result->SetIsolateNodesPropagateFuncGraphFlag(true);
  }
  return eval_result;
  return std::make_shared<EvalResult>(ret_base, nullptr);
 }

 AbstractBasePtrList FuncGraphEvaluator::NormalizeArgs(const AbstractBasePtrList &args_spec_list) const {
@@ -280,15 +258,15 @@ EvalResultPtr Evaluator::Run(AnalysisEnginePtr engine, const ConfigPtrList &args
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &conf) -> AbstractBasePtr {
                         MS_EXCEPTION_IF_NULL(conf);
                         return conf->GetEvaluatedValue()->abstract();
                         return conf->ObtainEvalResult()->abstract();
                       });
  args_spec_list = NormalizeArgs(args_spec_list);
  args_spec_list = BroadenUndeterminedArgs(args_spec_list);
  trace::TraceGraphEvalEnter(shared_from_base<Evaluator>(), out_conf);
  MS_LOG(DEBUG) << EvalEntryLogging(shared_from_base<Evaluator>(), args_spec_list, out_conf);
  MS_EXCEPTION_IF_NULL(cache_);
  auto iter = cache_->find(args_spec_list);
  if (iter == cache_->end()) {
  MS_EXCEPTION_IF_NULL(evaluator_cache_map_);
  auto iter = evaluator_cache_map_->find(args_spec_list);
  if (iter == evaluator_cache_map_->end()) {
    MS_LOG(DEBUG) << evaluator_name << " cache miss, call Eval().";
    EvalResultPtr ret = Eval(engine, args_spec_list);
    if (ret->abstract() == nullptr) {
@@ -296,7 +274,7 @@ EvalResultPtr Evaluator::Run(AnalysisEnginePtr engine, const ConfigPtrList &args
      MS_LOG(EXCEPTION) << "Evaluator " << evaluator_name << " result is nullptr.";
    }
    MS_LOG(DEBUG) << evaluator_name << " set cache. return: " << ret->abstract()->ToString() << ".";
    (*cache_)[args_spec_list] = ret;
    (*evaluator_cache_map_)[args_spec_list] = ret;
    trace::TraceGraphEvalLeave(shared_from_base<Evaluator>());
    return ret;
  } else {
@@ -315,7 +293,7 @@ EvalResultPtr TrivialPrimEvaluator::Run(AnalysisEnginePtr engine, const ConfigPt
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [is_py_eval](const ConfigPtr &conf) -> AbstractBasePtr {
                         MS_EXCEPTION_IF_NULL(conf);
                         auto abstract = conf->GetEvaluatedValue()->abstract();
                         auto abstract = conf->ObtainEvalResult()->abstract();
                         // broaden the ref_key, while infer python prim for cache
                         if (is_py_eval && abstract->isa<AbstractRef>()) {
                           auto abs_ref = abstract->cast<AbstractRefPtr>();
@@ -333,7 +311,7 @@ EvalResultPtr TransitionPrimEvaluator::Run(AnalysisEnginePtr engine, const Confi
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &conf) -> AbstractBasePtr {
                         MS_EXCEPTION_IF_NULL(conf);
                         return conf->GetEvaluatedValue()->abstract();
                         return conf->ObtainEvalResult()->abstract();
                       });
  if (args_conf_list.size() == 0) {
    MS_LOG(EXCEPTION) << "Size should greater than 0";
@@ -354,12 +332,12 @@ EvalResultPtr TrackedEvaluator::Run(AnalysisEnginePtr engine, const ConfigPtrLis
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &conf) -> AbstractBasePtr {
                         MS_EXCEPTION_IF_NULL(conf);
                         return conf->GetEvaluatedValue()->abstract();
                         return conf->ObtainEvalResult()->abstract();
                       });
  EvalResultPtr ret = sub_evaluator_->Run(engine, args_conf_list, out_conf);
  // Don't lookup from cache, as different out_conf with same node but different context
  // may add different entry to anfnode_config_map_, like getattr primitive.
  (*cache_)[args_spec_list] = ret;
  (*evaluator_cache_map_)[args_spec_list] = ret;
  return ret;
 }

@@ -369,11 +347,11 @@ EvalResultPtr PartialAppEvaluator::Run(AnalysisEnginePtr engine, const ConfigPtr
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &conf) -> AbstractBasePtr {
                         MS_EXCEPTION_IF_NULL(conf);
                         return conf->GetEvaluatedValue()->abstract();
                         return conf->ObtainEvalResult()->abstract();
                       });
  MS_EXCEPTION_IF_NULL(cache_);
  auto iter = cache_->find(args_spec_list);
  if (iter != cache_->end()) {
  MS_EXCEPTION_IF_NULL(evaluator_cache_map_);
  auto iter = evaluator_cache_map_->find(args_spec_list);
  if (iter != evaluator_cache_map_->end()) {
    return iter->second;
  }

@@ -386,7 +364,7 @@ EvalResultPtr PartialAppEvaluator::Run(AnalysisEnginePtr engine, const ConfigPtr
                       [](const AbstractBasePtr &arg) -> ConfigPtr { return std::make_shared<VirtualConfig>(arg); });
  EvalResultPtr ret = evaluator_->Run(engine, partial_args_conf_list, out_conf);

  (*cache_)[args_spec_list] = ret;
  (*evaluator_cache_map_)[args_spec_list] = ret;
  return ret;
 }

@@ -395,11 +373,11 @@ EvalResultPtr JEvaluator::Run(AnalysisEnginePtr engine, const ConfigPtrList &arg
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &conf) -> AbstractBasePtr {
                         MS_EXCEPTION_IF_NULL(conf);
                         return conf->GetEvaluatedValue()->abstract();
                         return conf->ObtainEvalResult()->abstract();
                       });
  MS_EXCEPTION_IF_NULL(cache_);
  auto iter = cache_->find(args_spec_list);
  if (iter != cache_->end()) {
  MS_EXCEPTION_IF_NULL(evaluator_cache_map_);
  auto iter = evaluator_cache_map_->find(args_spec_list);
  if (iter != evaluator_cache_map_->end()) {
    return iter->second;
  }

@@ -427,7 +405,7 @@ EvalResultPtr JEvaluator::Run(AnalysisEnginePtr engine, const ConfigPtrList &arg
  AbstractBasePtrList jargs = {result->abstract(), bprop};
  AbstractBasePtr jtuple = std::make_shared<AbstractTuple>(jargs);
  auto infer_reuslt = std::make_shared<EvalResult>(jtuple, std::make_shared<AttrValueMap>());
  (*cache_)[args_spec_list] = infer_reuslt;
  (*evaluator_cache_map_)[args_spec_list] = infer_reuslt;
  return infer_reuslt;
 }

--- a/mindspore/ccsrc/pipeline/jit/static_analysis/evaluator.h
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/evaluator.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -40,7 +40,7 @@ using EvaluatorAttrMapPtr = std::shared_ptr<EvaluatorAttrMap>;
 class Evaluator : public Base {
 public:
  explicit Evaluator(const std::string &id)
      : cache_(std::make_shared<EvaluatorCacheMap>()),
      : evaluator_cache_map_(std::make_shared<EvaluatorCacheMap>()),
        attr_cache_(std::make_shared<EvaluatorAttrMap>()),
        identifier_(id) {}
  ~Evaluator() override = default;
@@ -86,10 +86,10 @@ class Evaluator : public Base {

  virtual void set_bound_node(const AnfNodePtr &node) { bound_node_ = AnfNodeWeakPtr(node); }

  EvaluatorCacheMapPtr &cache() { return cache_; }
  EvaluatorCacheMapPtr &evaluator_cache_map() { return evaluator_cache_map_; }
  EvaluatorAttrMapPtr &attr_cache() { return attr_cache_; }

  EvaluatorCacheMapPtr cache_;
  EvaluatorCacheMapPtr evaluator_cache_map_;
  EvaluatorAttrMapPtr attr_cache_;
  std::string identifier_;

--- a/mindspore/ccsrc/pipeline/jit/static_analysis/prim.cc
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/prim.cc
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -53,7 +53,7 @@ EvalResultPtr DoSignatureEvaluator::Run(AnalysisEnginePtr engine, const ConfigPt
                                        AnfNodeConfigPtr out_conf) {
  AbstractBasePtrList args_spec_list;
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &ref) -> AbstractBasePtr { return ref->GetEvaluatedValue()->abstract(); });
                       [](const ConfigPtr &ref) -> AbstractBasePtr { return ref->ObtainEvalResult()->abstract(); });
  auto do_signature = prim_->cast<prim::DoSignaturePrimitivePtr>();
  auto &func = do_signature->function();
  if (func->isa<Primitive>()) {
@@ -145,7 +145,7 @@ EvalResultPtr UnpackGraphEvaluator::Run(AnalysisEnginePtr engine, const ConfigPt
  AnfNodePtrList args_inputs{out_node_inputs.begin() + 1, out_node_inputs.end()};
  AbstractBasePtrList args_spec_list;
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &ref) -> AbstractBasePtr { return ref->GetEvaluatedValue()->abstract(); });
                       [](const ConfigPtr &ref) -> AbstractBasePtr { return ref->ObtainEvalResult()->abstract(); });
  // get the forward graph
  MS_EXCEPTION_IF_NULL(args_spec_list[0]);
  auto fn = args_spec_list[0]->cast<AbstractFunctionPtr>();
@@ -244,7 +244,7 @@ EvalResultPtr MixedPrecisionCastEvaluator::Run(AnalysisEnginePtr engine, const C
                      << ", inputs size " << out_node_inputs.size();
  }
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &ref) -> AbstractBasePtr { return ref->GetEvaluatedValue()->abstract(); });
                       [](const ConfigPtr &ref) -> AbstractBasePtr { return ref->ObtainEvalResult()->abstract(); });

  ScopePtr scope = kDefaultScope;
  if (out_conf != nullptr) {
@@ -600,8 +600,8 @@ EvalResultPtr PythonPrimEvaluator::EvalPrim(const AnalysisEnginePtr &, const Abs
  }
  MS_LOG(DEBUG) << "Eval for:" << prim_py_->ToString();

  const auto &iter = cache_->find(args);
  if (iter != cache_->end()) {
  const auto &iter = evaluator_cache_map_->find(args);
  if (iter != evaluator_cache_map_->end()) {
    return iter->second;
  }
  auto py_args = PreparePyInputs(prim_py_, args);
@@ -614,7 +614,7 @@ EvalResultPtr PythonPrimEvaluator::EvalPrim(const AnalysisEnginePtr &, const Abs

  MS_LOG(DEBUG) << "Python InferTensor result spec: " << res_spec->ToString() << ".";
  auto infer_result = std::make_shared<EvalResult>(res_spec, std::make_shared<AttrValueMap>(added_attrs));
  (*cache_)[args] = infer_result;
  (*evaluator_cache_map_)[args] = infer_result;
  return infer_result;
 }

@@ -936,7 +936,7 @@ class EmbedEvaluator : public SymbolicPrimEvaluator {
    AnfNodeConfigPtr node_conf = dyn_cast<AnfNodeConfig>(args_conf_list[0]);
    MS_EXCEPTION_IF_NULL(node_conf);

    AbstractBasePtr x = node_conf->GetEvaluatedValue()->abstract();
    AbstractBasePtr x = node_conf->ObtainEvalResult()->abstract();
    x = SensitivityTransform(x);
    SymbolicKeyInstancePtr key = std::make_shared<SymbolicKeyInstance>(node_conf->node(), x);
    AbstractScalarPtr abs_scalar = std::make_shared<AbstractScalar>(key, std::make_shared<SymbolicKeyType>());
@@ -976,7 +976,7 @@ class RefToEmbedEvaluator : public SymbolicPrimEvaluator {
      MS_LOG(ERROR) << "Conf should be AnfNodeConfig";
      return nullptr;
    }
    AbstractBasePtr abs = node_conf->GetEvaluatedValue()->abstract();
    AbstractBasePtr abs = node_conf->ObtainEvalResult()->abstract();
    AbstractRefPtr ref_abs = abs->cast<AbstractRefPtr>();
    if (ref_abs == nullptr) {
      MS_LOG(ERROR) << "The first parameter of RefToEmbed should be Ref, but " << abs->ToString();
@@ -1040,7 +1040,7 @@ class GetAttrEvaluator : public TransitionPrimEvaluator {
    }
    // don't lookup from cache, as different out_conf with same node but different context
    // may add different entry to anfnode_config_map, like getattr primitive;
    (*cache_)[args_spec_list] = ret;
    (*evaluator_cache_map_)[args_spec_list] = ret;
    return ret;
  }
 };
@@ -1126,7 +1126,7 @@ class CreateInstanceEvaluator : public TransitionPrimEvaluator {

    AbstractBasePtr ret = ToAbstract(converted_ret, AnalysisContext::DummyContext(), out_conf);
    auto infer_result = std::make_shared<EvalResult>(ret, std::make_shared<AttrValueMap>());
    (*cache_)[args_spec_list] = infer_result;
    (*evaluator_cache_map_)[args_spec_list] = infer_result;
    return infer_result;
  }

@@ -1161,7 +1161,7 @@ class PartialEvaluator : public Evaluator {

    MS_EXCEPTION_IF_NULL(out_conf);
    MS_EXCEPTION_IF_NULL(out_conf->node());
    auto arg0_value = args_conf_list[0]->GetEvaluatedValue()->abstract();
    auto arg0_value = args_conf_list[0]->ObtainEvalResult()->abstract();
    AbstractBasePtrList args_spec_list{arg0_value};
    // Func in hypermap(partial(Func, arg0), arg1, arg2) may become Poly Node.
    if (arg0_value->isa<AbstractError>()) {
@@ -1169,7 +1169,7 @@ class PartialEvaluator : public Evaluator {
      MS_LOG(DEBUG) << "AbstractError for node: " << out_conf->node()->DebugString()
                    << " as func is: " << arg0_value->ToString();
      auto eval_result = std::make_shared<EvalResult>(ret, std::make_shared<AttrValueMap>());
      (*cache_)[args_spec_list] = eval_result;
      (*evaluator_cache_map_)[args_spec_list] = eval_result;
      return eval_result;
    }
    auto func = CheckArg<AbstractFunction>("partial", args_spec_list, 0);
@@ -1182,11 +1182,9 @@ class PartialEvaluator : public Evaluator {
      }
    }

    std::vector<EvalResultPtr> eval_result_list;
    (void)std::transform(args_conf_list.cbegin() + 1, args_conf_list.cend(), std::back_inserter(eval_result_list),
                         [](const ConfigPtr &config) -> EvalResultPtr { return config->GetEvaluatedValue(); });
    (void)std::transform(eval_result_list.cbegin(), eval_result_list.cend(), std::back_inserter(args_spec_list),
                         [](const EvalResultPtr &eval_result) -> AbstractBasePtr { return eval_result->abstract(); });
    (void)std::transform(
      args_conf_list.begin() + 1, args_conf_list.end(), std::back_inserter(args_spec_list),
      [](const ConfigPtr &config) -> AbstractBasePtr { return config->ObtainEvalResult()->abstract(); });
    AbstractBasePtrList args(args_spec_list.begin() + 1, args_spec_list.end());

    auto cnode = out_conf->node()->cast<CNodePtr>();
@@ -1195,25 +1193,16 @@ class PartialEvaluator : public Evaluator {
      MS_LOG(EXCEPTION) << "Out_conf node: " << cnode->DebugString()
                        << ", args_conf_list: " << mindspore::ToString(args_conf_list);
    }

    auto flag = std::any_of(eval_result_list.cbegin(), eval_result_list.cend(), [](const EvalResultPtr &eval_result) {
      MS_LOG(DEBUG) << "Propagate isolate nodes flag from: " << eval_result->abstract()->ToString()
                    << ", flag: " << eval_result->HasIsolateNodesPropagateCNodeFlag();
      return eval_result->HasIsolateNodesPropagateCNodeFlag();
    });
    AbstractFuncAtomPtrList partial_funcs_list;
    auto build_partial = [args, cnode, flag, &partial_funcs_list](const AbstractFuncAtomPtr &atom_func) {
    auto build_partial = [args, cnode, &partial_funcs_list](const AbstractFuncAtomPtr &atom_func) {
      auto new_func = std::make_shared<PartialAbstractClosure>(atom_func, args, cnode);
      partial_funcs_list.push_back(new_func);
      if (atom_func->HasIsolateNodesFlag() || flag) {
        new_func->SetIsolateNodesFlag(true);
      }
    };
    func->Visit(build_partial);

    auto ret = AbstractFunction::MakeAbstractFunction(partial_funcs_list);
    auto eval_result = std::make_shared<EvalResult>(ret, std::make_shared<AttrValueMap>());
    (*cache_)[args_spec_list] = eval_result;
    (*evaluator_cache_map_)[args_spec_list] = eval_result;
    return eval_result;
  }

--- a/mindspore/ccsrc/pipeline/jit/static_analysis/program_specialize.cc
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/program_specialize.cc
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -30,11 +30,11 @@
 namespace mindspore {
 namespace abstract {
 namespace {
 inline AbstractBasePtr GetEvaluatedValueWrap(const AnfNodeConfigPtr &conf) {
 inline AbstractBasePtr GetEvaluatedValue(const AnfNodeConfigPtr &conf) {
  if (conf->node()->intermediate_abstract()) {
    return conf->node()->intermediate_abstract();
  }
  return conf->GetEvaluatedValue()->abstract();
  return conf->ObtainEvalResult()->abstract();
 }

 AnfNodePtr BuildValueNode(const ValuePtr &v, const AbstractBasePtr &abs_base) {
@@ -80,7 +80,7 @@ std::shared_ptr<FuncGraphSpecializer> ProgramSpecializer::GetFuncGraphSpecialize
  if (iter != specializations_.end()) {
    return iter->second;
  }
  if (context->func_graph()) {
  if (context->func_graph() != nullptr) {
    MS_LOG(EXCEPTION) << "Specialize inner error";
  }
  return nullptr;
@@ -101,6 +101,9 @@ FuncGraphSpecializer::FuncGraphSpecializer(ProgramSpecializer *const s, const Fu
  cloner_ = SpecializerClone(fg, std::make_shared<TraceSpecialize>(GetNextCounter()));
  repl_node_ = cloner_->cloned_node();
  specialized_func_graph_ = cloner_->cloned_func_graph()[fg];
  todo_.push_back(fg->get_return());
  auto ps = fg->parameters();
  (void)todo_.insert(todo_.end(), ps.begin(), ps.end());
 }

 AnfNodePtr FuncGraphSpecializer::ReplicateDisconnectedNode(const AnfNodePtr &node) {
@@ -128,24 +131,12 @@ AnfNodePtr FuncGraphSpecializer::ReplicateDisconnectedNode(const AnfNodePtr &nod
    }
    auto c_node = node->cast<CNodePtr>();
    MS_EXCEPTION_IF_NULL(c_node);
    auto c_new_node = new_node->cast<CNodePtr>();
    MS_EXCEPTION_IF_NULL(c_new_node);
    auto inputs = c_node->inputs();
    std::vector<AnfNodePtr> new_inputs;
    (void)std::transform(
      inputs.begin(), inputs.end(), std::back_inserter(new_inputs), [this](const AnfNodePtr &inp) -> AnfNodePtr {
        auto new_inp = ReplicateDisconnectedNode(inp);
        // refer the comments in BuildReplacedNode.
        if (inp->isa<CNode>()) {
          auto c_inp = inp->cast<CNodePtr>();
          MS_EXCEPTION_IF_NULL(c_inp);
          auto c_new_inp = new_inp->cast<CNodePtr>();
          MS_EXCEPTION_IF_NULL(c_new_inp);
          MS_LOG(DEBUG) << "Replace inp node: " << inp->ToString() << " in order list, with " << new_inp->ToString();
          c_new_inp->func_graph()->ReplaceInOrder(c_inp, c_new_inp);
        }
        return new_inp;
      });
    (void)std::transform(inputs.begin(), inputs.end(), std::back_inserter(new_inputs),
                         [this](const AnfNodePtr &inp) -> AnfNodePtr { return ReplicateDisconnectedNode(inp); });
    auto c_new_node = new_node->cast<CNodePtr>();
    MS_EXCEPTION_IF_NULL(c_new_node);
    c_new_node->set_inputs(new_inputs);
  }

@@ -189,16 +180,7 @@ void FuncGraphSpecializer::Run() {
 }

 void FuncGraphSpecializer::FirstPass() {
  // Process parameter;
  for (const auto &node : func_graph_->parameters()) {
    (void)marked_.insert(node);
    ProcessNode(node);
  }
  ProcessIsolateNodes();

  todo_.push_back(func_graph_->get_return());

  while (!todo_.empty()) {
  while (todo_.size()) {
    AnfNodePtr node = todo_.back();
    todo_.pop_back();
    if (node->func_graph() == nullptr) {
@@ -227,41 +209,13 @@ void FuncGraphSpecializer::FirstPass() {

 // Specialize CNode in func graphs
 void FuncGraphSpecializer::SecondPass() {
  std::vector<CNodePtr> starts;
  auto &isolate_nodes = specialized_func_graph_->isolate_nodes();
  starts.reserve(isolate_nodes.size() + 1);
  starts.push_back(specialized_func_graph_->get_return());
  (void)std::transform(isolate_nodes.begin(), isolate_nodes.end(), std::back_inserter(starts),
                       [](auto &node) { return dyn_cast<CNode>(node); });
  for (auto &node : BroadFirstSearchGraphCNodes(starts)) {
  for (auto &node : BroadFirstSearchGraphCNodes({specialized_func_graph_->get_return()})) {
    if (node->isa<CNode>()) {
      ProcessCNode(node->cast<CNodePtr>());
    }
  }
 }

 static AnfNodePtr CreateNoBroadenDepend() {
  PrimitivePtr prim = std::make_shared<Primitive>(prim::kPrimDepend->name(), prim::kPrimDepend->attrs());
  prim->set_attr(ATTR_NO_BROADEN, prim::kValueOne);
  return BuildValueNode(prim, FromValueInside(prim));
 }

 bool AllowDependIsolateNodes(const AnfNodePtr &node) {
  auto abstract = node->abstract();
  if (abstract->GetTypeTrack()->isa<EnvType>()) {
    return false;
  }
  auto abstract_tuple = dyn_cast<abstract::AbstractTuple>(abstract);
  if (abstract_tuple != nullptr) {
    for (auto &abs : abstract_tuple->elements()) {
      if (abs->GetTypeTrack()->isa<EnvType>()) {
        return false;
      }
    }
  }
  return true;
 }

 void FuncGraphSpecializer::ProcessNode(const AnfNodePtr &node) {
  MS_EXCEPTION_IF_NULL(node);
  ScopeGuard scope_guard(node->scope());
@@ -275,7 +229,7 @@ void FuncGraphSpecializer::ProcessNode(const AnfNodePtr &node) {
                      << ", specialized_func_graph_: " << specialized_func_graph_->ToString();
    return;
  }
  new_node->set_abstract(GetEvaluatedValueWrap(conf));
  new_node->set_abstract(GetEvaluatedValue(conf));
  if (new_node->isa<CNode>() && new_node->abstract()->isa<PartialAbstractClosure>()) {
    auto partial_abstract = dyn_cast<PartialAbstractClosure>(new_node->abstract());
    if (partial_abstract->node() == node) {
@@ -286,7 +240,7 @@ void FuncGraphSpecializer::ProcessNode(const AnfNodePtr &node) {
  MS_LOG(DEBUG) << "Set new_node: " << new_node->ToString() << ", abstract as: " << new_node->abstract()->ToString();

  if (node->isa<CNode>()) {
    auto attrs = conf->GetEvaluatedValue()->attribute();
    auto attrs = conf->ObtainEvalResult()->attribute();
    auto c_old = node->cast<CNodePtr>();
    auto c_new = new_node->cast<CNodePtr>();
    auto new_inputs = c_new->inputs();
@@ -294,33 +248,19 @@ void FuncGraphSpecializer::ProcessNode(const AnfNodePtr &node) {
    for (size_t i = 0; i < old_inputs.size(); ++i) {
      auto node_input = old_inputs[i];
      AnfNodeConfigPtr iconf = MakeConfig(node_input);
      auto eval_result = iconf->GetEvaluatedValue();
      AbstractBasePtr ival = eval_result->abstract();
      AbstractBasePtr ival = GetEvaluatedValue(iconf);
      // First try to check if node_input can be replaced by a ValueNode. If cannot, then try to check if
      // can be replaced by another CNode from anfnode_config_map, otherwise use the replicated node.
      AnfNodePtr replace_node = BuildPossibleValueNode(iconf->node(), ival, attrs);
      if (replace_node == nullptr) {
        replace_node = BuildReplacedNode(iconf).second;
        replace_node = BuildReplacedNode(iconf);
        MS_EXCEPTION_IF_NULL(replace_node);
        replace_node->set_abstract(ival);
        MS_LOG(DEBUG) << "Set replaced: " << replace_node->ToString() << ", to abstract: " << ival->ToString();
      } else if (node_input->isa<CNode>() && eval_result->HasIsolateNodesPropagateCNodeFlag()) {
        // Handle isolate nodes
        auto inp_c_node = node_input->cast<CNodePtr>();
        auto collected = CollectCNodeWithIsolateNodes(inp_c_node, eval_result, c_new->func_graph());
        if (AllowDependIsolateNodes(collected)) {
          auto depend_ops = CreateNoBroadenDepend();
          AnfNodePtr new_cnode = specialized_func_graph_->NewCNode({depend_ops, replace_node, collected});
          new_cnode->set_abstract(ival);
          replace_node = new_cnode;
          MS_LOG(DEBUG) << "Build possible depend node for node: " << node_input->DebugString()
                        << ", ival: " << ival->ToString() << ", replace_node: " << replace_node->DebugString();
        }
      } else {
        MS_LOG(DEBUG) << "Not set replace value node for node: " << node_input->DebugString()
                      << ", ival: " << ival->ToString() << ", replace_node: " << replace_node->DebugString();
        MS_LOG(DEBUG) << "Build possible value node for node: " << node_input->DebugString()
                      << ", ival: " << ival->ToString() << ", replace_node: " << replace_node->ToString();
      }

      if (new_inputs[i] != replace_node) {
        new_inputs[i] = replace_node;
        MS_LOG(DEBUG) << "Set new_input[" << i << "] = " << replace_node->DebugString();
@@ -330,112 +270,17 @@ void FuncGraphSpecializer::ProcessNode(const AnfNodePtr &node) {
  }
 }

 AnfNodePtr FuncGraphSpecializer::CollectCNodeWithIsolateNodes(const CNodePtr &c_node,
                                                              const EvalResultPtr &c_node_eval_result,
                                                              const FuncGraphPtr &new_fg) {
  auto c_node_inputs = c_node->inputs();
  auto inp0 = c_node_inputs[0];
  auto inp0_conf = MakeConfig(inp0);
  auto inp0_eval_result = inp0_conf->GetEvaluatedValue();
  auto inp0_abstract = inp0_eval_result->abstract();

  auto inp0_abs_func = inp0_abstract->cast<AbstractFunctionPtr>();
  if (inp0_abs_func == nullptr) {
    MS_LOG_EXCEPTION << "inp0 should be AbstractFunction, but: " << inp0_abstract->ToString();
  }

  if (c_node_eval_result->HasIsolateNodesPropagateFuncGraphFlag() || inp0_abs_func->HasIsolateNodesFlag()) {
    auto c_node_conf = MakeConfig(c_node);
    auto replace_node = BuildReplacedNode(c_node_conf).second;
    MS_EXCEPTION_IF_NULL(replace_node);
    replace_node->set_abstract(inp0_abstract);
    MS_LOG(DEBUG) << "Build possible depend node for node: " << c_node->DebugString()
                  << ", depend node: " << replace_node->DebugString();
    return replace_node;
  }

  // Search inputs from 1 to find CNodeWithIsolateNode if that input is CNode and can Built PossibleValueNode.
  std::vector<AnfNodePtr> collected_nodes;
  for (std::size_t i = 1; i < c_node_inputs.size(); ++i) {
    auto inp_i = c_node_inputs[i];
    if (inp_i->isa<CNode>()) {
      auto inp_i_conf = MakeConfig(inp_i);
      auto inp_i_eval_result = inp_i_conf->GetEvaluatedValue();
      auto inp_i_abstract = inp_i_eval_result->abstract();
      if (inp_i_eval_result->HasIsolateNodesPropagateCNodeFlag()) {
        static auto attrs = std::make_shared<AttrValueMap>();
        AnfNodePtr replace_node = BuildPossibleValueNode(inp_i, inp_i_abstract, attrs);
        if (replace_node == nullptr) {
          replace_node = BuildReplacedNode(inp_i_conf).second;
          MS_EXCEPTION_IF_NULL(replace_node);
          replace_node->set_abstract(inp_i_abstract);
          MS_LOG(DEBUG) << "Set replaced: " << replace_node->DebugString() << ", to replace: " << c_node->DebugString();
        } else {
          auto inp_i_c_node = inp_i->cast<CNodePtr>();
          AnfNodePtr new_node = GetReplicatedNode(inp_i_c_node);
          auto collected = CollectCNodeWithIsolateNodes(inp_i_c_node, inp_i_eval_result, new_node->func_graph());
          replace_node = collected;
        }
        collected_nodes.push_back(replace_node);
      }
    }
  }
  // Build depend node;
  if (collected_nodes.empty()) {
    MS_LOG_EXCEPTION << "cannot find where IsolateNodes from, node: " << c_node->DebugString()
                     << ", abstract: " << c_node_eval_result->abstract()->ToString()
                     << ", flag: " << c_node_eval_result->HasIsolateNodesPropagateCNodeFlag();
  }
  if (collected_nodes.size() == 1) {
    auto new_cnode = collected_nodes[0];
    MS_LOG(DEBUG) << "Build possible depend node for node: " << c_node->DebugString()
                  << ", depend node: " << new_cnode->DebugString();
    return new_cnode;
  }
  AbstractBasePtrList tuple_abstract;
  std::transform(collected_nodes.cbegin(), collected_nodes.cend(), std::back_inserter(tuple_abstract),
                 [](const auto &collected_node) { return collected_node->abstract(); });
  auto make_tuple_ops = BuildValueNode(prim::kPrimMakeTuple, FromValueInside(prim::kPrimMakeTuple));
  collected_nodes.insert(collected_nodes.begin(), make_tuple_ops);
  AnfNodePtr new_cnode = new_fg->NewCNode(collected_nodes);
  new_cnode->set_abstract(std::make_shared<AbstractTuple>(tuple_abstract));
  MS_LOG(DEBUG) << "Build possible depend node for node: " << c_node->DebugString()
                << ", depend node: " << new_cnode->DebugString(2);

  return new_cnode;
 }

 void FuncGraphSpecializer::ProcessIsolateNodes() {
  // Process isolate nodes, take the isolate cnode as one because it may be forward to a new cnode.
  for (const auto &node : func_graph_->isolate_nodes()) {
    ScopeGuard scope_guard(node->scope());
    auto conf = MakeConfig(node);
    // First of node_pair is the original node or the forwarded node, second is the replaced node.
    const auto &node_pair = BuildReplacedNode(conf);
    auto &replace_node = node_pair.first;
    MS_EXCEPTION_IF_NULL(replace_node);
    replace_node->set_abstract(GetEvaluatedValueWrap(conf));
    MS_LOG(DEBUG) << "BuildReplacedNode for isolate node, new_node: " << replace_node->DebugString()
                  << ", old node: " << node->DebugString();
    // Only the isolated node is forwarded, mark node as processed. Otherwise node is pushed to todo_ in
    // BuildReplacednode and will be processed as normal node.
    if (node != node_pair.first) {
      (void)marked_.insert(node);
    }
  }
 }

 std::pair<AnfNodePtr, AnfNodePtr> FuncGraphSpecializer::BuildReplacedNode(const AnfNodeConfigPtr &conf) {
 AnfNodePtr FuncGraphSpecializer::BuildReplacedNode(const AnfNodeConfigPtr &conf) {
  MS_EXCEPTION_IF_NULL(conf);

  auto conf_iter = engine_->anfnode_config_map().find(conf);
  AnfNodeConfigPtr new_conf = conf;
  while (conf_iter != engine_->anfnode_config_map().end()) {
    MS_LOG(DEBUG) << "Origin conf: , node(" << new_conf->node()->DebugString() << ")";
    MS_LOG(DEBUG) << "Origin conf: node(" << new_conf->node()->DebugString() << ")";
    new_conf = conf_iter->second;
    MS_EXCEPTION_IF_NULL(new_conf);
    const auto &forward_node = new_conf->node();
    MS_LOG(DEBUG) << "Replaced conf: , node(" << forward_node->DebugString() << ")";
    MS_LOG(DEBUG) << "Replaced conf: node(" << forward_node->DebugString() << ")";
    const auto &replicated_forward_node = ReplicateDisconnectedNode(forward_node);
    if (replicated_forward_node && replicated_forward_node->isa<CNode>()) {
      // The AnfNode in order_list can be:
@@ -476,7 +321,7 @@ std::pair<AnfNodePtr, AnfNodePtr> FuncGraphSpecializer::BuildReplacedNode(const
    MS_LOG(DEBUG) << "Set repl: graph(nullptr), node(" << repl->DebugString()
                  << ") to replace origin: " << new_conf->node()->DebugString();
  }
  return std::make_pair(new_conf->node(), repl);
  return repl;
 }

 namespace {
@@ -515,6 +360,7 @@ AnfNodePtr FuncGraphSpecializer::BuildSpecializedNode(const AnfNodePtr &node, co
                        << ", abstract: " << abs->ToString();
    }
  }

  // Set the flag, so this MetaFuncGraph will be Re-AutoMonaded.
  if (func->isa<MetaFuncGraphAbstractClosure>()) {
    auto specialized_fg = GetValueNode<FuncGraphPtr>(repl);
@@ -522,7 +368,6 @@ AnfNodePtr FuncGraphSpecializer::BuildSpecializedNode(const AnfNodePtr &node, co
      specialized_fg->set_flag(mindspore::kFuncGraphFlagReAutoMonad, true);
    }
  }

  return repl;
 }

@@ -614,7 +459,7 @@ AnfNodePtr FuncGraphSpecializer::BuildSpecializedParameterNode(const CNodePtr &n
      MS_LOG(EXCEPTION) << "Size of cnode: " << cnode->DebugString()
                        << " is not equal to 2 added to size of args: " << mindspore::ToString(partial_closure->args());
    }
    static auto attrs = std::make_shared<AttrValueMap>();
    auto attrs = std::make_shared<AttrValueMap>();
    for (size_t i = 0; i < partial_closure->args().size(); i++) {
      auto old_node = cnode->input(i + 2);
      auto possibile_value_node = BuildPossibleValueNode(old_node, partial_closure->args()[i], attrs);
@@ -636,8 +481,8 @@ AnfNodePtr FuncGraphSpecializer::BuildSpecializedParameterNode(const CNodePtr &n
 const EvaluatorCacheMapPtr &FuncGraphSpecializer::GetEvalCache(const EvaluatorPtr &eval) {
  auto cache_iter = evalcaches_.find(eval);
  if (cache_iter == evalcaches_.end()) {
    evalcaches_[eval] = eval->cache();
    return eval->cache();
    evalcaches_[eval] = eval->evaluator_cache_map();
    return eval->evaluator_cache_map();
  }
  return cache_iter->second;
 }
@@ -693,7 +538,7 @@ void FuncGraphSpecializer::ProcessCNode(const CNodePtr &new_node) {
  std::vector<AnfNodePtr> args(new_inputs.begin() + 1, new_inputs.end());
  // CNode(CNode(Partial, f, arg1), arg2, ...) --> CNode(f, arg1, arg2, ...)
  while (IsPrimitiveCNode(func, prim::kPrimPartial)) {
    auto &inputs = func->cast<CNodePtr>()->inputs();
    std::vector<AnfNodePtr> inputs = func->cast<CNodePtr>()->inputs();
    // First element is partial, second is func so arg is start from 2
    (void)args.insert(args.begin(), inputs.begin() + 2, inputs.end());
    func = inputs[1];
@@ -788,7 +633,7 @@ SpecializeStatusCode FuncGraphSpecializer::FindUniqueArgvals(const AbstractFunct
  MS_EXCEPTION_IF_NULL(eval);
  MS_EXCEPTION_IF_NULL(result);

  EvaluatorCacheMap evaluator_cache_map = *eval->cache();
  EvaluatorCacheMap evaluator_cache_map = *eval->evaluator_cache_map();
  if (evaluator_cache_map.find(argvals) != evaluator_cache_map.end()) {
    *result = std::make_pair(argvals, evaluator_cache_map[argvals]->abstract());
    return kSpecializeSuccess;
@@ -848,22 +693,6 @@ static PrimitivePtr BuildPrimtiveValueWithAttributes(const PrimitivePtr &prim, c
  return prim;
 }

 // Return true if this node can be replaced by value.
 static bool CanReplaceByValue(const AnfNodePtr &node) {
  auto cnode = dyn_cast<CNode>(node);
  if (cnode == nullptr || cnode->inputs().empty()) {
    return true;
  }
  auto &input0 = cnode->inputs().at(0);
  // Keep parameter not be replaced by value.
  if (input0->isa<Parameter>()) {
    return false;
  }
  // Keep 'depend' node not be replaced by value.
  auto prim = GetValueNode<PrimitivePtr>(input0);
  return !IsPrimitiveEquals(prim, prim::kPrimDepend);
 }

 AnfNodePtr FuncGraphSpecializer::BuildPossibleValueNode(const AnfNodePtr &origin_node, const AbstractBasePtr &ival,
                                                        const AttrValueMapPtr &attrs) {
  MS_EXCEPTION_IF_NULL(origin_node);
@@ -904,7 +733,8 @@ AnfNodePtr FuncGraphSpecializer::BuildPossibleValueNode(const AnfNodePtr &origin
    if (val->isa<AnyValue>()) {
      return nullptr;
    }
    if (!CanReplaceByValue(origin_node)) {
    // keep primitive 'depend' not to be optimized
    if (IsPrimitiveCNode(origin_node, prim::kPrimDepend)) {
      return nullptr;
    }
    return BuildValueNode(val, ival);
--- a/mindspore/ccsrc/pipeline/jit/static_analysis/program_specialize.h
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/program_specialize.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -98,8 +98,6 @@ class FuncGraphSpecializer : public std::enable_shared_from_this<FuncGraphSpecia
  void ProcessNode(const AnfNodePtr &node);
  void ProcessCNode(const CNodePtr &new_node);

  void ProcessIsolateNodes();

  AnfNodeConfigPtr MakeConfig(const AnfNodePtr &node);
  inline void AddTodoItem(const AnfNodePtr &node) { todo_.push_back(node); }
  // Get node replicated by Cloner.
@@ -114,12 +112,9 @@ class FuncGraphSpecializer : public std::enable_shared_from_this<FuncGraphSpecia
  // Build a value node if ival is constant and not any-value
  AnfNodePtr BuildPossibleValueNode(const AnfNodePtr &origin_node, const AbstractBasePtr &ival,
                                    const AttrValueMapPtr &attrs);
  // Build a replaceable node for iconf->node; it may be a replicated forward CNode in static analysis or just a
  // replicated node. First of returned pair is the origin node or the forward cnode, second is the replaced node.
  std::pair<AnfNodePtr, AnfNodePtr> BuildReplacedNode(const AnfNodeConfigPtr &conf);
  // Collect CNodes which have IsolateNodes that will be replaced by a ValuedNode.
  AnfNodePtr CollectCNodeWithIsolateNodes(const CNodePtr &c_node, const EvalResultPtr &c_node_eval_result,
                                          const FuncGraphPtr &new_fg);
  // Build a replaceable node for iconf->node; it may be a replicated forwarded CNode in static analysis or just a
  // replicated node.
  AnfNodePtr BuildReplacedNode(const AnfNodeConfigPtr &conf);
  // Build a specialized node from given argvals;
  AnfNodePtr BuildSpecializedNode(const AnfNodePtr &node, const AbstractBasePtr &abs,
                                  const AbstractBasePtrList &argvals);
--- a/mindspore/ccsrc/pipeline/jit/static_analysis/static_analysis.cc
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/static_analysis.cc
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -58,7 +58,7 @@ void AnalysisCache::set_value(const AnfNodeConfigPtr &conf, const EvalResultPtr
  MS_LOG(DEBUG) << "AnalysisCache set for NodeConfig: " << conf->node()->DebugString()
                << ", Context: " << conf->context()->ToString() << ", Value: " << result->abstract()->ToString()
                << ", Pointer: " << result->abstract().get();
  cache_[conf] = result;
  analysis_cache_map_[conf] = result;

  // Set intermediate abstract value.
  if (IsIntermediateAbstract(result->abstract())) {
@@ -77,8 +77,8 @@ void AnalysisCache::set_value(const AnfNodeConfigPtr &conf, const EvalResultPtr
 }

 EvalResultPtr AnalysisCache::GetValue(const AnfNodeConfigPtr &conf) {
  auto value = cache_.find(conf);
  if (value == cache_.end()) {
  auto value = analysis_cache_map_.find(conf);
  if (value == analysis_cache_map_.end()) {
    return nullptr;
  }
  return value->second;
@@ -124,7 +124,7 @@ AnalysisResult AnalysisEngine::Run(const FuncGraphPtr &func_graph, const Abstrac

  AnalysisResult result;
  MS_EXCEPTION_IF_NULL(output_conf);
  result.inferred = output_conf->GetEvaluatedValue();
  result.inferred = output_conf->ObtainEvalResult();
  result.context = root_context;
  return result;
 }
@@ -136,25 +136,24 @@ AnalysisContextPtr AnalysisEngine::Run(const FuncGraphPtr &func_graph, const Ana
  return eval->graph_context();
 }

 EvalResultPtr AnalysisEngine::GetEvaluatedValue(const AnfNodeConfigPtr &conf) {
 EvalResultPtr AnalysisEngine::ObtainEvalResultWithCache(const AnfNodeConfigPtr &conf) {
  MS_EXCEPTION_IF_NULL(conf);
  auto value = cache_.GetValue(conf);
  if (value != nullptr) {
    MS_LOG(DEBUG) << "Evaluate cache hit for NodeConfig: " << conf->ToString() << ", Value: " << value->abstract().get()
                  << ", " << value->abstract()->ToString() << ", flag: " << value->HasIsolateNodesPropagateCNodeFlag();
    return value;
  EvalResultPtr result = analysis_cache_.GetValue(conf);
  if (result != nullptr) {
    MS_LOG(DEBUG) << "Evaluate cache hit for NodeConfig: " << conf->ToString()
                  << ", Value: " << result->abstract().get() << ", " << result->abstract()->ToString();
    return result;
  }

  MS_LOG(DEBUG) << "Evaluate cache miss for NodeConfig: " << conf->ToString();
  value = Eval(conf);
  if (value == nullptr) {
  result = Eval(conf);
  if (result == nullptr) {
    MS_LOG(EXCEPTION) << "Evaluate for NodeConfig " << conf->ToString() << " get nullptr";
  }
  MS_LOG(DEBUG) << "Evaluate node on demond for NodeConfig: " << conf->ToString()
                << ", Value: " << value->abstract().get() << ", " << value->abstract()->ToString()
                << ", flag: " << value->HasIsolateNodesPropagateCNodeFlag();
  cache_.set_value(conf, value);
  return value;
                << ", result: " << result->abstract().get() << ", " << result->abstract()->ToString();
  analysis_cache_.set_value(conf, result);
  return result;
 }

 EvalResultPtr AnalysisEngine::Eval(const AnfNodeConfigPtr &conf) {
@@ -198,8 +197,7 @@ EvalResultPtr AnalysisEngine::Eval(const AnfNodeConfigPtr &conf) {
                      << " NodeInfo: " << trace::GetDebugInfo(node->debug_info());
  }
 #endif
  MS_LOG(DEBUG) << "End Eval NodeConfig " << conf->ToString() << ", res: " << eval_result->abstract()->ToString()
                << ", flag: " << eval_result->HasIsolateNodesPropagateCNodeFlag();
  MS_LOG(DEBUG) << "End Eval NodeConfig " << conf->ToString() << ", res: " << eval_result->abstract()->ToString();
  return eval_result;
 }

@@ -251,20 +249,6 @@ AbstractBasePtr AnalysisEngine::EvalValueNode(const ValueNodePtr &value_node, co
  return out;
 }

 static bool CheckIsolateNodesPropagateFlag(const AbstractFunctionPtr &abs_func, const ConfigPtrList &conf_list) {
  if (abs_func->HasIsolateNodesFlag()) {
    MS_LOG(DEBUG) << "Propagate isolate nodes flag from: " << abs_func->ToString();
    return true;
  }
  auto flag = std::any_of(conf_list.cbegin(), conf_list.cend(), [](const ConfigPtr &conf) {
    auto eval_result = conf->GetEvaluatedValue();
    MS_LOG(DEBUG) << "Propagate isolate nodes flag from: " << eval_result->abstract()->ToString()
                  << ", flag: " << eval_result->HasIsolateNodesPropagateCNodeFlag();
    return eval_result->HasIsolateNodesPropagateCNodeFlag();
  });
  return flag;
 }

 EvalResultPtr AnalysisEngine::EvalCNode(const CNodePtr &cnode, const AnfNodeConfigPtr &conf) {
  MS_EXCEPTION_IF_NULL(conf);
  MS_EXCEPTION_IF_NULL(cnode);
@@ -280,10 +264,10 @@ EvalResultPtr AnalysisEngine::EvalCNode(const CNodePtr &cnode, const AnfNodeConf
  AnfNodeConfigPtr func_conf = MakeConfig(func_node, context);
  MS_EXCEPTION_IF_NULL(func_conf);
  // Keep it in a local variable, otherwise smart pointer will free it.
  auto maybe_func_eval_result = func_conf->GetEvaluatedValue();
  auto maybe_func_eval_result = func_conf->ObtainEvalResult();
  AbstractBasePtr maybe_func = maybe_func_eval_result->abstract();
  if (maybe_func == nullptr) {
    MS_LOG(EXCEPTION) << "func_conf.GetEvaluatedValue() return null, func_conf: " << func_conf->ToString()
    MS_LOG(EXCEPTION) << "No abstract, func_conf: " << func_conf->ToString()
                      << " NodeInfo: " << trace::GetDebugInfo(cnode->debug_info());
  }
  if (maybe_func->BuildType()->type_id() == kObjectTypeUndeterminedType) {
@@ -292,8 +276,7 @@ EvalResultPtr AnalysisEngine::EvalCNode(const CNodePtr &cnode, const AnfNodeConf
  }
  AbstractFunctionPtr func = dyn_cast<AbstractFunction>(maybe_func);
  if (func == nullptr) {
    MS_LOG(EXCEPTION) << "func_conf.GetEvaluatedValue() return not AbstractFunction: " << maybe_func->ToString()
                      << ", func_conf: " << func_conf->ToString()
    MS_LOG(EXCEPTION) << "Not AbstractFunction: " << maybe_func->ToString() << ", func_conf: " << func_conf->ToString()
                      << " NodeInfo: " << trace::GetDebugInfo(cnode->debug_info());
  }

@@ -313,21 +296,6 @@ EvalResultPtr AnalysisEngine::EvalCNode(const CNodePtr &cnode, const AnfNodeConf
  func->Visit(build_evaluator);

  auto eval_result = ExecuteEvaluators(infs, conf, args_conf_list);
  auto flag = CheckIsolateNodesPropagateFlag(func, args_conf_list);
  if (flag != eval_result->HasIsolateNodesPropagateCNodeFlag()) {
    MS_LOG(DEBUG) << "Different propagate isolate nodes flag from: " << eval_result->abstract()->ToString()
                  << ", cnode flag: " << eval_result->HasIsolateNodesPropagateCNodeFlag()
                  << ", funcgraph flag: " << eval_result->HasIsolateNodesPropagateFuncGraphFlag()
                  << ", check flag:" << flag;
    // This eval_result may be fetch from an Evaluator's cache based on args_spec_list equality.
    // But args may be come from different CNode, so propagate flag is not same,
    // a new copy of eval_result should be used.
    auto new_eval_result = eval_result->Clone();
    // FuncGraph flag should be used for HOF call or used FuncGraph propagate.
    flag = flag | new_eval_result->HasIsolateNodesPropagateFuncGraphFlag();
    new_eval_result->SetIsolateNodesPropagateCNodeFlag(flag);
    eval_result = new_eval_result;
  }
  return eval_result;
 }

@@ -349,25 +317,25 @@ void AnalysisEngine::ClearEvaluatorCache() {
  for (std::pair<AbstractFunctionPtr, EvaluatorPtr> element : constructors_) {
    EvaluatorPtr evaluator = element.second;
    MS_EXCEPTION_IF_NULL(evaluator);
    MS_EXCEPTION_IF_NULL(evaluator->cache());
    evaluator->cache()->clear();
    MS_EXCEPTION_IF_NULL(evaluator->evaluator_cache_map());
    evaluator->evaluator_cache_map()->clear();
  }
  for (auto &element : prim_constructors_) {
    EvaluatorPtr evaluator = element.second;
    MS_EXCEPTION_IF_NULL(evaluator);
    MS_EXCEPTION_IF_NULL(evaluator->cache());
    evaluator->cache()->clear();
    MS_EXCEPTION_IF_NULL(evaluator->evaluator_cache_map());
    evaluator->evaluator_cache_map()->clear();
  }
  for (auto &element : prim_py_evaluators_) {
    EvaluatorPtr evaluator = element.second;
    MS_EXCEPTION_IF_NULL(evaluator);
    MS_EXCEPTION_IF_NULL(evaluator->cache());
    evaluator->cache()->clear();
    MS_EXCEPTION_IF_NULL(evaluator->evaluator_cache_map());
    evaluator->evaluator_cache_map()->clear();
  }
 }

 void AnalysisEngine::Clear() {
  cache_.Clear();
  analysis_cache_.Clear();
  anfnode_config_map_.clear();
  eval_trace_.clear();
  constructors_.clear();
@@ -586,7 +554,7 @@ EvalResultPtr AnalysisEngine::ForwardConfig(const AnfNodeConfigPtr &orig_conf, c
    }
  }
  forward_count_++;
  auto res = GetEvaluatedValue(new_conf);
  auto res = ObtainEvalResultWithCache(new_conf);
  forward_count_--;
  return res;
 }
@@ -651,7 +619,7 @@ EvaluatorPtr AnalysisEngine::HandleNestedRecursion(const std::vector<EvaluatorPt
  for (auto u_eval : undetermined_evals) {
    MS_LOG(DEBUG) << u_eval.evaluator_->ToString() << "check undetermined.";
    auto &alternate_evaluator = multi_poss_[u_eval.evaluator_];
    auto &eval_cache = alternate_evaluator->cache();
    auto &eval_cache = alternate_evaluator->evaluator_cache_map();
    const auto &alt_eval_args = EvaluatorArgs(alternate_evaluator, args_spec_list);
    if ((!undetermined_evals.count(alt_eval_args)) &&
        (((!continued_evals_.count(u_eval)) && (eval_cache->find(args_spec_list) != eval_cache->end())) ||
@@ -698,7 +666,7 @@ EvalResultPtr AnalysisEngine::ExecuteMultipleEvaluators(const std::vector<Evalua
  (void)std::transform(args_conf_list.begin(), args_conf_list.end(), std::back_inserter(args_spec_list),
                       [](const ConfigPtr &conf) -> AbstractBasePtr {
                         MS_EXCEPTION_IF_NULL(conf);
                         return conf->GetEvaluatedValue()->abstract();
                         return conf->ObtainEvalResult()->abstract();
                       });
  for (auto eval : evaluators) {
    SetUndeterminedFlag(eval);
@@ -741,9 +709,9 @@ EvalResultPtr AnalysisEngine::ExecuteMultipleEvaluators(const std::vector<Evalua
  return ProcessEvalResults(out_specs);
 }

 EvalResultPtr AnfNodeConfig::GetEvaluatedValue() {
 EvalResultPtr AnfNodeConfig::ObtainEvalResult() {
  AnfNodeConfigPtr self = shared_from_base<AnfNodeConfig>();
  return engine_.lock()->GetEvaluatedValue(self);
  return engine_.lock()->ObtainEvalResultWithCache(self);
 }

 abstract::AbstractBasePtr MakeAbstractClosure(const FuncGraphPtr &func_graph,
--- a/mindspore/ccsrc/pipeline/jit/static_analysis/static_analysis.h
+++ b/mindspore/ccsrc/pipeline/jit/static_analysis/static_analysis.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -46,9 +46,6 @@ namespace abstract {
 using AttrValueMap = std::unordered_map<std::string, ValuePtr>;
 using AttrValueMapPtr = std::shared_ptr<AttrValueMap>;

 inline const int kIsolateNodesPropagateCNodeFlag = 1;
 inline const int kIsolateNodesPropagateFuncGraphFlag = 2;

 // the class to save evaluated result: abstract value and modified attribute
 class EvalResult : public Base {
 public:
@@ -58,43 +55,10 @@ class EvalResult : public Base {
  AbstractBasePtr abstract() { return abstract_; }
  AttrValueMapPtr attribute() { return attribute_; }

  std::shared_ptr<EvalResult> Clone() const {
    auto cloned = std::make_shared<EvalResult>(abstract_, attribute_);
    cloned->SetIsolateNodesPropagateCNodeFlag(HasIsolateNodesPropagateCNodeFlag());
    cloned->SetIsolateNodesPropagateFuncGraphFlag(HasIsolateNodesPropagateFuncGraphFlag());
    return cloned;
  }
  // The related AbstractBase is evaluated from CNode which input has isolate nodes.
  // This flag is propagated to all user node.
  // When a node A can be specialized to a ValueNode, we should check if that node A has this flag,
  // if it has, then the original FuncGraph call should be depended, so it's side effect will not
  // be lost.
  bool HasIsolateNodesPropagateCNodeFlag() const {
    auto iter = eval_attr_.find(kIsolateNodesPropagateCNodeFlag);
    if (iter != eval_attr_.end()) {
      return GetValue<bool>(iter->second);
    }
    return false;
  }
  void SetIsolateNodesPropagateCNodeFlag(bool flag) { eval_attr_[kIsolateNodesPropagateCNodeFlag] = MakeValue(flag); }

  // FuncGraph itself may not have IsoloateNodes, but the used FuncGraph or HOF call may have IsolateNodes;
  bool HasIsolateNodesPropagateFuncGraphFlag() const {
    auto iter = eval_attr_.find(kIsolateNodesPropagateFuncGraphFlag);
    if (iter != eval_attr_.end()) {
      return GetValue<bool>(iter->second);
    }
    return false;
  }
  void SetIsolateNodesPropagateFuncGraphFlag(bool flag) {
    eval_attr_[kIsolateNodesPropagateFuncGraphFlag] = MakeValue(flag);
  }

 private:
  AbstractBasePtr abstract_;
  // Attribute related to PrimEvaluator;
  AttrValueMapPtr attribute_;
  std::unordered_map<int, ValuePtr> eval_attr_;
 };
 using EvalResultPtr = std::shared_ptr<EvalResult>;

@@ -104,7 +68,7 @@ class Config : public Base {
  Config() = default;
  ~Config() override = default;
  MS_DECLARE_PARENT(Config, Base);
  virtual EvalResultPtr GetEvaluatedValue() = 0;
  virtual EvalResultPtr ObtainEvalResult() = 0;
 };

 // Config will be stored in AnalysisCache
@@ -132,7 +96,7 @@ class AnfNodeConfig : public Config {
  ~AnfNodeConfig() override = default;
  MS_DECLARE_PARENT(AnfNodeConfig, Config);

  EvalResultPtr GetEvaluatedValue() override;
  EvalResultPtr ObtainEvalResult() override;

  AnalysisContextPtr context() const { return context_; }

@@ -182,7 +146,7 @@ class VirtualConfig : public Config {

  ~VirtualConfig() override = default;
  MS_DECLARE_PARENT(VirtualConfig, Config);
  EvalResultPtr GetEvaluatedValue() override {
  EvalResultPtr ObtainEvalResult() override {
    return std::make_shared<EvalResult>(abstract_, std::make_shared<AttrValueMap>());
  }

@@ -195,12 +159,12 @@ class AnalysisCache {
 public:
  AnalysisCache() = default;
  ~AnalysisCache() = default;
  void Clear() { cache_.clear(); }
  void Clear() { analysis_cache_map_.clear(); }
  void set_value(const AnfNodeConfigPtr &conf, const EvalResultPtr &arg);
  EvalResultPtr GetValue(const AnfNodeConfigPtr &conf);

 private:
  std::unordered_map<AnfNodeConfigPtr, EvalResultPtr, AnfNodeConfigHasher, AnfNodeConfigEqual> cache_;
  std::unordered_map<AnfNodeConfigPtr, EvalResultPtr, AnfNodeConfigHasher, AnfNodeConfigEqual> analysis_cache_map_;
 };

 using PrimEvaluatorMap = std::unordered_map<PrimitivePtr, EvaluatorPtr, PrimitiveHasher, PrimitiveEqual>;
@@ -222,7 +186,9 @@ struct PartialAppHasher {
 class AnalysisEngine : public std::enable_shared_from_this<AnalysisEngine> {
 public:
  AnalysisEngine(const PrimEvaluatorMap &prim_evaluator_map, const FuncGraphManagerPtr &func_graph_manager)
      : cache_(AnalysisCache()), prim_constructors_(prim_evaluator_map), func_graph_manager_(func_graph_manager) {
      : analysis_cache_(AnalysisCache()),
        prim_constructors_(prim_evaluator_map),
        func_graph_manager_(func_graph_manager) {
    function_call_depth_ = 0;
    forward_count_ = 0;
  }
@@ -231,7 +197,7 @@ class AnalysisEngine : public std::enable_shared_from_this<AnalysisEngine> {
  // func_graph: The func_graph to analyze.
  // args_spec_list: The abstracted arguments for the func_graph. Must be a tuple of AbstractBase.
  AnalysisResult Run(const FuncGraphPtr &func_graph, const AbstractBasePtrList &args_spec_list);
  EvalResultPtr GetEvaluatedValue(const AnfNodeConfigPtr &conf);
  EvalResultPtr ObtainEvalResultWithCache(const AnfNodeConfigPtr &conf);
  // Return the Evaluator for the given function.
  EvaluatorPtr GetEvaluatorFor(const AbstractFunctionPtr &fn);

@@ -241,7 +207,7 @@ class AnalysisEngine : public std::enable_shared_from_this<AnalysisEngine> {
  EvalResultPtr Execute(const AbstractFunctionPtr &fn, const AbstractBasePtrList &args_spec_list);
  void Clear();
  void ClearEvaluatorCache();
  AnalysisCache &cache() { return cache_; }
  AnalysisCache &analysis_cache() { return analysis_cache_; }
  AnfNodeConfigPtr MakeConfig(const AnfNodePtr &node, const AnalysisContextPtr &context) {
    return std::make_shared<AnfNodeConfig>(shared_from_this(), node, context);
  }
@@ -262,7 +228,7 @@ class AnalysisEngine : public std::enable_shared_from_this<AnalysisEngine> {
  EvalResultPtr ForwardConfig(const AnfNodeConfigPtr &orig_conf, const AnfNodeConfigPtr new_conf);
  const PrimEvaluatorMap &PrimConstructors() const { return prim_constructors_; }

  AnalysisCache cache_;
  AnalysisCache analysis_cache_;
  std::unordered_map<PrimitivePyPtr, EvaluatorPtr> prim_py_evaluators_;

  void ResetFunctionCallDepth() { function_call_depth_ = 0; }
--- a/mindspore/core/abstract/abstract_function.h
+++ b/mindspore/core/abstract/abstract_function.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -58,11 +58,6 @@ class AbstractFuncUnion : public AbstractFunction {
  bool operator==(const AbstractFunction &other) const override;
  std::size_t hash() const override;
  AbstractFunctionPtr Copy() const override { MS_LOG(EXCEPTION) << "Cannot Copy from AbstractFuncUnion"; }
  bool HasIsolateNodesFlag() const override {
    bool flag = std::any_of(func_list_.cbegin(), func_list_.cend(),
                            [](const AbstractFunctionPtr &func) { return func->HasIsolateNodesFlag(); });
    return flag;
  }

 private:
  AbstractFuncAtomPtrList func_list_;
@@ -131,8 +126,6 @@ class FuncGraphAbstractClosure : public AbstractFuncAtom {

  std::string ToString() const override;

  bool HasIsolateNodesFlag() const override { return !func_graph_->isolate_nodes().empty(); }

 private:
  FuncGraphPtr func_graph_;
  AnalysisContextPtr context_;
@@ -202,16 +195,12 @@ class PartialAbstractClosure : public AbstractFuncAtom {
  std::size_t hash() const override;

  std::string ToString() const override;
  bool HasIsolateNodesFlag() const override { return isolate_nodes_flag_; }
  void SetIsolateNodesFlag(bool flag) { isolate_nodes_flag_ = flag; }

 private:
  AbstractFuncAtomPtr fn_;
  AbstractBasePtrList args_spec_list_;
  // The CNode which this PartialAbstractClosure evaluated from.
  AnfNodeWeakPtr node_;
  // If the bound fn_ has isolate ndoes or arguments evaluated from function has isolate nodes.
  bool isolate_nodes_flag_{false};
 };
 using PartialAbstractClosurePtr = std::shared_ptr<PartialAbstractClosure>;

--- a/mindspore/core/abstract/abstract_value.h
+++ b/mindspore/core/abstract/abstract_value.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -207,8 +207,6 @@ class AbstractFunction : public AbstractBase {
  virtual AnfNodePtr tracking_id() const { return nullptr; }
  virtual void set_tracking_id(AnfNodePtr) {}
  virtual AnalysisContextPtr context() const { return nullptr; }
  // Function which itself has IsolateNodes, not include used function or HOF.
  virtual bool HasIsolateNodesFlag() const { return false; }
 };
 using AbstractFunctionPtrList = std::vector<AbstractFunctionPtr>;

--- a/mindspore/core/abstract/param_validator.cc
+++ b/mindspore/core/abstract/param_validator.cc
@@ -157,8 +157,8 @@ void CheckShapeAllPositive(const std::string &op, const ShapeVector &shape) {
 void CheckShapeAnyAndPositive(const std::string &op, const ShapeVector &shape) {
  for (size_t i = 0; i < shape.size(); ++i) {
    if ((shape[i] < 0) && (shape[i] != Shape::SHP_ANY)) {
      MS_LOG(EXCEPTION) << op << " shape element [" << i << "] must be positive integer or SHP_ANY, but got "
                        << shape[i];
      MS_EXCEPTION(ValueError) << op << " shape element [" << i << "] must be positive integer or SHP_ANY, but got "
                               << shape[i];
    }
  }
 }
--- a/mindspore/core/ir/anf.h
+++ b/mindspore/core/ir/anf.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -65,7 +65,7 @@ using CNodePtrList = std::vector<CNodePtr>;

 class FuncGraph;
 using FuncGraphSet = OrderedSet<FuncGraphPtr>;
 using FuncGraphPtrList = std::vector<FuncGraphPtr>;
 using FuncGraphVector = std::vector<FuncGraphPtr>;

 class Primitive;
 using PrimitivePtr = std::shared_ptr<Primitive>;
--- a/mindspore/core/ir/func_graph.cc
+++ b/mindspore/core/ir/func_graph.cc
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -602,7 +602,7 @@ void FuncGraph::EraseUnusedNodeInOrder() {
    // Erase unused cnode.
    for (auto it = order_.begin(); it != order_.end();) {
      if (!all_nodes.contains(*it)) {
        MS_LOG(DEBUG) << "Remove node " << (*it)->ToString() << " in graph " << ToString() << " order.";
        MS_LOG(DEBUG) << "Remove node: " << (*it)->ToString() << " in graph " << ToString() << " order.";
        it = order_.erase(it);
        continue;
      }
@@ -616,7 +616,7 @@ void FuncGraph::EraseUnusedNodeInOrder(const AnfNodePtr &node) {
    auto cnode = node->cast<CNodePtr>();
    if (cnode) {
      order_.erase(cnode);
      MS_LOG(DEBUG) << "Remove the node" << node->DebugString() << " from order list.";
      MS_LOG(DEBUG) << "Remove node: " << node->DebugString() << " from order list.";
    }
  }
 }
@@ -648,40 +648,6 @@ void FuncGraph::ReplaceInOrder(const AnfNodePtr &old_node, const AnfNodePtr &new
  // Remove old node from order list.
  // Unused children nodes can be cleared by EraseUnusedNodeInOrder().
  order_.erase(iter);
  // Replace isolate node if it is.
  ReplaceIsolateNode(old_node, new_node);
 }

 void FuncGraph::ReplaceIsolateNode(const AnfNodePtr &old_node, const AnfNodePtr &new_node) {
  if (isolate_nodes_.erase(old_node) == 0) {
    // Skip if old node is not an isloate node.
    return;
  }
  if (!new_node->isa<CNode>()) {
    // Isolate node can not replaced by a non-cnode.
    LOG(WARNING) << "Try replace isolate node: " << old_node->DebugString() << " with: " << new_node->DebugString();
    return;
  }
  // Replace old node with the new one.
  isolate_nodes_.insert(new_node);
  // Replace isloate node in manager.
  auto graph_manager = manager();
  if (graph_manager != nullptr) {
    graph_manager->ReplaceIsolateNode(old_node, new_node);
  }
 }

 const std::vector<AnfNodePtr> FuncGraph::GetIsolateNodesInOrder() const {
  if (isolate_nodes_.empty()) {
    return {};
  }
  if (isolate_nodes_.size() == 1) {
    return std::vector<AnfNodePtr>(isolate_nodes_.cbegin(), isolate_nodes_.cend());
  }
  std::vector<AnfNodePtr> ordered_isolate_nodes;
  std::copy_if(order_.cbegin(), order_.cend(), std::back_inserter(ordered_isolate_nodes),
               [&](const auto &node) { return isolate_nodes_.find(node) != isolate_nodes_.end(); });
  return ordered_isolate_nodes;
 }

 static std::vector<AnfNodePtr> MakeInputNodes(const PrimitivePtr &primitive, const std::vector<AnfNodePtr> &inputs) {
--- a/mindspore/core/ir/func_graph.h
+++ b/mindspore/core/ir/func_graph.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -94,8 +94,8 @@ class AbstractFunction;
 using AbstractFunctionPtr = std::shared_ptr<AbstractFunction>;
 }  // namespace abstract

 // ANF transform class
 // either a primitive or a func_graph
 // ANF transform class.
 // Either a primitive or a func_graph.
 class FuncGraphTransform {
 public:
  enum Type { kGtPrimitive, kGtFuncGraph };
@@ -156,11 +156,11 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
  ~FuncGraph() override = default;
  MS_DECLARE_PARENT(FuncGraph, FuncGraphBase);

  // get the graph's abstract
  // Get the graph's abstract.
  abstract::AbstractFunctionPtr abstract();
  abstract::AbstractBasePtr ToAbstract() override;

  // return the graph's output, or nullptr if not yet deduced
  // Return the graph's output, or nullptr if not yet deduced.
  AnfNodePtr output() const;
  void set_output(const AnfNodePtr &value, bool force_new_ret = false);

@@ -169,28 +169,28 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
  void add_parameter(const ParameterPtr &p);
  void append_parameter(const ParameterPtr &p) { parameters_.push_back(p); }
  void set_parameters(const std::vector<AnfNodePtr> &params) { parameters_ = params; }
  // add a weight parameter with specific name
  // Add a weight parameter with specific name.
  ParameterPtr AddWeightParameter(const std::string &name);

  // create a cnode with given inputs, bound to this graph
  // Create a cnode with given inputs, bound to this graph.
  virtual CNodePtr NewCNode(const std::vector<AnfNodePtr> &inputs = std::vector<AnfNodePtr>());
  virtual CNodePtr NewCNode(const PrimitivePtr &primitive, const std::vector<AnfNodePtr> &prim_inputs);

  // create a cnode with given inputs, bound to this graph and push back to order list.
  // Create a cnode with given inputs, bound to this graph and push back to order list.
  CNodePtr NewCNodeInOrder(const std::vector<AnfNodePtr> &inputs = std::vector<AnfNodePtr>());
  CNodePtr NewCNodeInOrder(const PrimitivePtr &primitive, const std::vector<AnfNodePtr> &prim_inputs);

  // create a cnode with given inputs, bound to this graph and push back to front of order list.
  // Create a cnode with given inputs, bound to this graph and push back to front of order list.
  CNodePtr NewCNodeInFront(const std::vector<AnfNodePtr> &inputs = std::vector<AnfNodePtr>());

  // create a cnode with given inputs, put it to order list before the position node.
  // Create a cnode with given inputs, put it to order list before the position node.
  CNodePtr NewCNodeBefore(const AnfNodePtr &position, const std::vector<AnfNodePtr> &inputs);

  // create a cnode with given inputs, put it to order list after the position node.
  // Create a cnode with given inputs, put it to order list after the position node.
  CNodePtr NewCNodeAfter(const AnfNodePtr &position, const std::vector<AnfNodePtr> &inputs);

  virtual ParameterPtr add_weight(const tensor::MetaTensorPtr &meta_tensor);
  // Functions for handling variable argument, keyword-only arguments and variable keyword argument
  // Functions for handling variable argument, keyword-only arguments and variable keyword argument.
  AnfNodePtr GetDefaultValueByName(const std::string &name);
  void set_param_default_value(const std::string &name, const AnfNodePtr &node) {
    parameter_default_value_[name] = node;
@@ -253,56 +253,56 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
    }
    this->debug_info_ = info;
  }
  // clear all info from manager
  // Clear all info from manager.
  void ClearAllManagerInfo();
  // get all nodes belonging to this func graph
  // Get all nodes belonging to this func graph.
  const AnfNodeSet &nodes();
  void CopyNodes(const FuncGraphPtr &source);
  void ClearNodes();
  void AddNode(AnfNodePtr node);
  void DropNode(AnfNodePtr node);

  // get all value_nodes belonging to this func graph
  // Get all value_nodes belonging to this func graph.
  const AnfNodeCounterMap &value_nodes();
  void CopyValueNodes(const FuncGraphPtr &source);
  void ClearValueNodes();
  void AddValueNode(AnfNodePtr node, int count = 1);
  void DropValueNode(AnfNodePtr node);

  // get all free vars directly used in this func graph
  // Get all free vars directly used in this func graph.
  const AnfNodeCounterMap &free_variables();
  void CopyFreeVariables(const FuncGraphPtr &source);
  void ClearFreeVariables();
  bool AddFreeVariable(AnfNodePtr node, int count = 1);
  bool DropFreeVariable(AnfNodePtr node);

  // get all vars required by this func graph
  // Get all vars required by this func graph.
  const BaseRefCounterMap &free_variables_total();

  // Return the set of graphs free_variables_total belong to.
  std::vector<AnfNodePtr> free_variables_nodes();

  // get all vars that are func graphs
  // Get all vars that are func graphs
  std::vector<FuncGraphPtr> free_variables_func_graphs();

  // get all value nodes of func graph directly used by this func graph
  // Get all value nodes of func graph directly used by this func graph.
  const FuncGraphCounterMap &func_graphs_used();
  void CopyFuncGraphsUsed(const FuncGraphPtr &source);
  void ClearFuncGraphsUsed();
  bool AddFuncGraphUsed(FuncGraphPtr fg, int count = 1);
  bool DropFuncGraphUsed(FuncGraphPtr fg);

  // get all value nodes in the inputs of J directly used by this func graph
  // Get all value nodes in the inputs of J directly used by this func graph.
  const std::unordered_map<AnfNodePtr, int> &j_value_nodes();
  void CopyJValueNodes(const FuncGraphPtr &source);
  void ClearJValueNodes();
  void AddJValueNode(const AnfNodePtr &value_node, int count = 1);
  void DropJValueNode(const AnfNodePtr &value_node);

  // get all func graphs nested used by this func graph
  // Get all func graphs nested used by this func graph.
  const FuncGraphSet &func_graphs_used_total();

  // get all user value nodes of this func graph, by CNode and its input's index
  // Get all user value nodes of this func graph, by CNode and its input's index.
  const CNodeIndexCounterMap &func_graph_cnodes_index();
  void CopyFuncGraphCNodesIndex(const FuncGraphPtr &source);
  void ClearFuncGraphCNodesIndex();
@@ -318,10 +318,10 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
  // Return the scope of this graph, scope have graph self but children not have.
  const FuncGraphSet &scope();

  // Return whether this graph is recursive
  // Return whether this graph is recursive.
  bool recursive();

  // Return graphs which forms a recursive loop
  // Return graphs which forms a recursive loop.
  std::shared_ptr<std::list<FuncGraphPtr>> recursive_graphs();

  std::size_t hash() const override { return std::hash<const FuncGraph *>{}(this); }
@@ -353,7 +353,7 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
  std::unordered_map<std::string, ValuePtr> attrs_;
  std::vector<BaseShapePtr> joined_shapes_;
  std::unordered_map<std::string, FuncGraphTransform> transforms_;
  // parameter default value
  // Parameter default value.
  std::map<std::string, AnfNodePtr> parameter_default_value_;
  size_t seen_;

@@ -377,21 +377,6 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
  // Clear cnode order list.
  void ClearOrderList() { order_.clear(); }

  // Gets nodes that not related to output, e.g. side-effect calls.
  const std::set<AnfNodePtr> &isolate_nodes() const { return isolate_nodes_; }

  // Add an isolate node.
  void AddIsolateNode(const AnfNodePtr &node) { isolate_nodes_.insert(node); }

  // Replace an isolate node.
  void ReplaceIsolateNode(const AnfNodePtr &old_node, const AnfNodePtr &new_node);

  // Clear isolate nodes.
  void ClearIsolateNodes() { isolate_nodes_.clear(); }

  // Get isolate nodes with order as OrderList.
  const std::vector<AnfNodePtr> GetIsolateNodesInOrder() const;

  bool stub() const { return stub_; }
  void set_stub(bool stub) { stub_ = stub; }
  static void set_drawer(Drawer drawer) { drawer_ = drawer; }
@@ -402,54 +387,51 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
  void set_stage(int64_t stage) { stage_ = stage; }

 private:
  // graph is manipulated by manager and others
  // Graph is manipulated by manager and others.
  friend FuncGraphManager;

  // all nodes of the function
  // All nodes of the function.
  AnfNodeSet nodes_;

  // all value nodes of the function
  // All value nodes of the function.
  AnfNodeCounterMap value_nodes_;

  // all func graph value nodes of the function
  // All func graph value nodes of the function.
  FuncGraphCounterMap func_graphs_used_;

  // all free variables of the function
  // All free variables of the function.
  AnfNodeCounterMap free_variables_;

  // all value nodes calling J in the function
  // All value nodes calling J in the function.
  std::unordered_map<AnfNodePtr, int> j_value_nodes_;

  // all user value nodes of this func graph, recording by CNode and its input's index
  // All user value nodes of this func graph, recording by CNode and its input's index.
  CNodeIndexCounterMap func_graph_cnodes_index_;

  // parameters of this function
  // Parameters of this function.
  std::vector<AnfNodePtr> parameters_;

  // global parameters used by this function.
  // Global parameters used by this function.
  std::vector<AnfNodePtr> used_global_parameters_;

  // isolate nodes, i.e. nodes that not related to output.
  std::set<AnfNodePtr> isolate_nodes_;

  // whether there is a *args and **kwargs, and count kwonlyargs'number
  // Whether there is a *args and **kwargs, and count kwonlyargs'number.
  bool has_vararg_;
  bool has_kwarg_;
  int kwonlyargs_count_;
  // the hyper param is placed on the top graph,
  // and positioned in the end of the param list, so we record the number to trace the position
  // Hyper param is placed on the top graph,
  // and positioned in the end of the param list, so we record the number to trace the position.
  size_t hyper_param_count_;
  // the argument input list for the graph used to generate this graph
  // Argument input list for the graph used to generate this graph.
  bool is_generated_;

  bool is_bprop_;

  // the cnode that calls 'return' primitive
  // we use shared pointer to manage it.
  // CNode that calls 'return' primitive.
  // We use shared pointer to manage it.
  CNodePtr return_;

  // back-ref to its manager
  // hold a weak ref to FuncGraphManager as FuncGraphManager also hold many ref to FuncGraph.
  // Back-ref to its manager.
  // Hold a weak ref to FuncGraphManager as FuncGraphManager also hold many ref to FuncGraph.
  // Otherwise, FuncGraph and FuncGraphManager will make a reference cycles.
  // Notes: Normally, there will be a global FuncGraphManager, it will hold all FuncGraphs.
  // In some ut test cases, they may use local FuncGraphManager in function which
@@ -464,12 +446,12 @@ class FuncGraph : public FuncGraphBase, public EffectInfoHolder {
                             const std::vector<AnfNodePtr> &kwarg_keys_tuple_nodes,
                             const std::vector<AnfNodePtr> &kwarg_values_tuple_nodes);

  // CNode order which relates to origin code order
  // CNode order which relates to origin code order.
  OrderedSet<CNodePtr> order_;
  bool stub_;
  inline static Drawer drawer_ = nullptr;
  // Design switch_layer_input as a ptr to
  // share between derived backpropagator and cloned graphs
  // share between derived backpropagator and cloned graphs.
  std::shared_ptr<bool> switch_layer_input_;
  int64_t stage_;
  std::unordered_map<AbstractBasePtrList, FuncGraphPtr, abstract::AbstractBasePtrListHasher,
--- a/mindspore/core/ir/func_graph_cloner.cc
+++ b/mindspore/core/ir/func_graph_cloner.cc
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -30,7 +30,7 @@

 // namespace to support intermediate representation definition
 namespace mindspore {
 Cloner::Cloner(const FuncGraphPtrList &func_graphs, bool clone_all_valuenodes, bool clone_all_child_graphs,
 Cloner::Cloner(const FuncGraphVector &func_graphs, bool clone_all_valuenodes, bool clone_all_child_graphs,
               bool clone_all_used_graphs, const TraceInfoPtr &relation, const TraceInfoPtr &target_relation)
    : clone_all_valuenodes_(clone_all_valuenodes),
      clone_all_child_graphs_(clone_all_child_graphs),
@@ -473,7 +473,6 @@ void Cloner::CloneAllNodes(const FuncGraphPtr &func_graph, const FuncGraphPtr &t
  // Only func_graph is inlined, it cannot be found in repl;
  if (repl_func_graph_.find(func_graph) != repl_func_graph_.end()) {
    CloneOrderList(func_graph, target_func_graph);
    CloneIsolateNodes(func_graph, target_func_graph);
  }
 }

@@ -499,15 +498,6 @@ void Cloner::CloneOrderList(const FuncGraphPtr &func_graph, const FuncGraphPtr &
  }
 }

 void Cloner::CloneIsolateNodes(const FuncGraphPtr &func_graph, const FuncGraphPtr &target_func_graph) {
  for (auto &node : func_graph->isolate_nodes()) {
    auto it = repl_node_.find(node);
    if (it != repl_node_.end()) {
      target_func_graph->AddIsolateNode(it->second);
    }
  }
 }

 void Cloner::Run() {
  if (todo_.empty()) {
    return;
@@ -515,7 +505,7 @@ void Cloner::Run() {

  if (type_ < kLifting) {
    // Basic and Inline Clone
    FuncGraphPtrList func_graphs;
    FuncGraphVector func_graphs;
    (void)std::transform(todo_.begin(), todo_.end(), std::back_inserter(func_graphs),
                         [](const CloneInfo &item) -> FuncGraphPtr { return item.origin; });
    manager_ = Manage(func_graphs, false);
@@ -654,7 +644,7 @@ FuncGraphPtr LiftingClone(const FuncGraphPtr &func_graph) {

 ClonerPtr SpecializerClone(const FuncGraphPtr &func_graph, const TraceInfoPtr &relation) {
  MS_EXCEPTION_IF_NULL(func_graph);
  FuncGraphPtrList func_graphs = {func_graph};
  FuncGraphVector func_graphs = {func_graph};
  ClonerPtr cloner =
    std::make_shared<Cloner>(func_graphs, false, false, false, std::make_shared<TraceCopy>(), relation);
 #ifdef ENABLE_PROFILE
--- a/mindspore/core/ir/func_graph_cloner.h
+++ b/mindspore/core/ir/func_graph_cloner.h
@@ -1,5 +1,5 @@
 /**
 * Copyright 2019 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -44,7 +44,7 @@ struct CloneInfo {

 class Cloner {
 public:
  explicit Cloner(const FuncGraphPtrList &func_graphs = {}, bool clone_all_valuenodes = false,
  explicit Cloner(const FuncGraphVector &func_graphs = {}, bool clone_all_valuenodes = false,
                  bool clone_all_child_graphs = true, bool clone_all_used_graphs = false,
                  const TraceInfoPtr &relation = std::make_shared<TraceCopy>(),
                  const TraceInfoPtr &target_relation = nullptr);
@@ -84,7 +84,6 @@ class Cloner {
  bool CheckStatus(const FuncGraphPtr &func_graph, bool is_inline);
  void CloneAllNodes(const FuncGraphPtr &func_graph, const FuncGraphPtr &target_func_graph);
  void CloneOrderList(const FuncGraphPtr &func_graph, const FuncGraphPtr &target_func_graph);
  void CloneIsolateNodes(const FuncGraphPtr &func_graph, const FuncGraphPtr &target_func_graph);
  void CloneFuncGraphValueNodes(const FuncGraphPtr &func_graph, const FuncGraphPtr &target_func_graph);
  void CloneFuncGraphDefaultValues(const FuncGraphPtr &func_graph, const FuncGraphPtr &target_func_graph);
  void InlineCloneParameters(const FuncGraphPtr &func_graph, const AnfNodePtrList &params);
--- a/mindspore/core/ir/manager.cc
+++ b/mindspore/core/ir/manager.cc
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -188,7 +188,7 @@ bool FuncGraphManager::func_graph_j_total(const FuncGraphPtr &fg) const {
  return j_total_->j_total_analysis()[fg];
 }

 // add a func graph to this manager, optionally as a root func graph.
 // Add a func graph to this manager, optionally as a root func graph.
 void FuncGraphManager::AddFuncGraph(FuncGraphPtr func_graph, bool is_root) {
  MS_EXCEPTION_IF_NULL(func_graph);
  if (is_root) {
@@ -198,26 +198,23 @@ void FuncGraphManager::AddFuncGraph(FuncGraphPtr func_graph, bool is_root) {
    return;
  }

  // Add func_graph as a managed graph.
  AddIntoManaged(func_graph);

  // New nodes to be acquired.
  std::vector<AnfNodePtr> new_nodes = func_graph->parameters();
  new_nodes.emplace_back(func_graph->get_return());
  auto &isolate_nodes = func_graph->isolate_nodes();
  new_nodes.insert(new_nodes.end(), isolate_nodes.begin(), isolate_nodes.end());

  // Add func_graph as a managed graph.
  AddIntoManaged(func_graph);

  // Acquire all nodes from func_graph.
  AcquireNodes(new_nodes);
 }

 // clear the all information in manager
 // Clear the all information in manager
 void FuncGraphManager::Clear() {
  func_graphs_.clear();
  all_nodes_.clear();
  node_users_.clear();
  roots_.clear();
  isolate_nodes_.clear();

  signals_->InvalidateComputer();
 }
@@ -282,8 +279,6 @@ void FuncGraphManager::AddIntoManaged(const FuncGraphPtr &fg) {
    FuncGraphManagerPtr this_manager = shared_from_this();
    fg->set_manager(this_manager);
  }
  const auto &fg_isolate_nodes = fg->isolate_nodes();
  isolate_nodes_.insert(fg_isolate_nodes.begin(), fg_isolate_nodes.end());
  func_graphs_.add(fg);
 }

@@ -641,29 +636,6 @@ void FuncGraphManager::CommitChanges(const std::vector<Change> &changes) {
  MaybeDropFuncGraphs(*drop_func_graphs);
 }

 void FuncGraphManager::ReplaceIsolateNode(const AnfNodePtr &old_node, const AnfNodePtr &new_node) {
  MS_EXCEPTION_IF_NULL(old_node);
  MS_EXCEPTION_IF_NULL(new_node);
  if (isolate_nodes_.erase(old_node) == 0) {
    return;
  }
  if (!new_node->isa<CNode>()) {
    MS_LOG(EXCEPTION) << "Replace isolate node: " << old_node->DebugString()
                      << " with non-cnode: " << new_node->DebugString();
  }
  isolate_nodes_.insert(new_node);
 }

 void FuncGraphManager::ClearIsolateNodes() {
  // If FuncGraph A has IsolateNode which input is FuncGraph B, B had been add to FuncGraph A's valuenode
  // by AddFuncGraph api, so if that isolate node is totoaly unused after AutoMonad, FuncGraph B should
  // be removed from FuncGraph A's valuenode, otherwise it will confuse FVTotalComputer.
  std::vector<AnfNodePtr> isolate_nodes_vec(isolate_nodes_.cbegin(), isolate_nodes_.cend());
  auto drop_func_graphs = MaybeDropNodes(isolate_nodes_vec);
  MaybeDropFuncGraphs(*drop_func_graphs);
  isolate_nodes_.clear();
 }

 void FuncGraphTransaction::SetParameters(FuncGraphPtr fg, const std::vector<AnfNodePtr> &params) {
  changes_.emplace_back(Change::kTxSetParams, ArgsOfSetParams{fg, params});
 }
--- a/mindspore/core/ir/manager.h
+++ b/mindspore/core/ir/manager.h
@@ -1,7 +1,7 @@
 /**
 * This is the C++ adaptation and derivative work of Myia (https://github.com/mila-iqia/myia/).
 *
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 * Copyright 2019-2021 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
@@ -351,15 +351,6 @@ class FuncGraphManager : public std::enable_shared_from_this<FuncGraphManager> {

  IncludeType Limit(const AnfNodePtr &node);

  // Gets isolate nodes that not related to output, e.g. side-effect calls.
  const std::set<AnfNodePtr> &isolate_nodes() const { return isolate_nodes_; }

  // Replace node in isolate node list.
  void ReplaceIsolateNode(const AnfNodePtr &old_node, const AnfNodePtr &new_node);

  // Clear all isolate nodes.
  void ClearIsolateNodes();

  // Static Analysis
  NodeUsersMap node_users_;
  AnfNodeSet all_nodes_;  // managed nodes
@@ -379,8 +370,8 @@ class FuncGraphManager : public std::enable_shared_from_this<FuncGraphManager> {
  void DropEdge(AnfNodePtr node, int index, AnfNodePtr input);
  void MoveAllNodes(FuncGraphPtr source, FuncGraphPtr target);

  FuncGraphSet roots_;        // managed roots
  FuncGraphSet func_graphs_;  // managed func graphs
  FuncGraphSet roots_;        // Managed roots.
  FuncGraphSet func_graphs_;  // Managed func graphs.

  std::shared_ptr<Signals> signals_;

@@ -393,9 +384,6 @@ class FuncGraphManager : public std::enable_shared_from_this<FuncGraphManager> {
  std::shared_ptr<RecursiveComputer> recursive_;
  std::shared_ptr<FuncGraphJTotalComputer> j_total_;

  // Isolate Nodes
  std::set<AnfNodePtr> isolate_nodes_;

  bool is_manage_;
  std::function<IncludeType(AnfNodePtr)> limit_;
 };
--- a/mindspore/lite/tools/converter/anf_transform.cc
+++ b/mindspore/lite/tools/converter/anf_transform.cc
@@ -301,7 +301,7 @@ FuncGraphPtr AnfTransform::TransformSingleFuncGraph(const FuncGraphPtr &old_grap
  return new_graph;
 }

 STATUS AnfTransform::GetAllFuncGraph(const FuncGraphPtr &main_graph, FuncGraphPtrList *subgraphs,
 STATUS AnfTransform::GetAllFuncGraph(const FuncGraphPtr &main_graph, FuncGraphVector *subgraphs,
                                     std::vector<ValueNodePtr> *vnodes) {
  auto nodes = TopoSort(main_graph->get_return());
  for (auto &node : nodes) {
@@ -324,7 +324,7 @@ FuncGraphPtr AnfTransform::Transform(const FuncGraphPtr &main_graph, const conve
  }

  // transform sub_graph
  FuncGraphPtrList subgraphs{};
  FuncGraphVector subgraphs{};
  std::vector<ValueNodePtr> vnodes{};
  int ret = GetAllFuncGraph(main_graph, &subgraphs, &vnodes);
  if (ret != RET_OK) {
--- a/mindspore/lite/tools/converter/anf_transform.h
+++ b/mindspore/lite/tools/converter/anf_transform.h
@@ -36,8 +36,7 @@ class AnfTransform {
  FuncGraphPtr Transform(const FuncGraphPtr &old_graph, const converter::Flags *config = nullptr);

 private:
  STATUS GetAllFuncGraph(const FuncGraphPtr &main_graph, FuncGraphPtrList *subgraphs,
                         std::vector<ValueNodePtr> *vnodes);
  STATUS GetAllFuncGraph(const FuncGraphPtr &main_graph, FuncGraphVector *subgraphs, std::vector<ValueNodePtr> *vnodes);
  FuncGraphPtr TransformSingleFuncGraph(const FuncGraphPtr &old_graph, const converter::Flags *config = nullptr);
  std::unique_ptr<quant::Quantizer> mQuantizer = nullptr;

--- a/tests/st/ops/cpu/test_dot_op.py
+++ b/tests/st/ops/cpu/test_dot_op.py
@@ -174,8 +174,8 @@ def test_dot_008():
    network = NetDot()
    try:
        network(x2_tensor, x1_tensor)
    except ValueError as e:
        assert ValueError == type(e)
    except IndexError as e:
        assert IndexError == type(e)


@pytest.mark.level0
--- a/tests/ut/python/nn/test_nn_embedding.py
+++ b/tests/ut/python/nn/test_nn_embedding.py
@@ -82,7 +82,7 @@ def test_check_multifield_embedding_false_type_field_id():

@non_graph_engine
 def test_check_multifield_embedding_false_input_shape():
    with pytest.raises(ValueError):
    with pytest.raises(IndexError):
        compile_multi_field_embedding((8,), (8, 200), (8, 200),
                                      dtype.int16, dtype.float32, dtype.int16)

--- a/tests/ut/python/nn/test_ssim.py
+++ b/tests/ut/python/nn/test_ssim.py
@@ -84,7 +84,7 @@ def test_ssim_different_shape():
    img1 = Tensor(np.random.random(shape_1))
    img2 = Tensor(np.random.random(shape_2))
    net = SSIMNet()
    with pytest.raises(TypeError):
    with pytest.raises(ValueError):
        _executor.compile(net, img1, img2)


@@ -108,9 +108,9 @@ def test_ssim_invalid_5d_input():
    invalid_img2 = Tensor(np.random.random(invalid_shape))

    net = SSIMNet()
    with pytest.raises(TypeError):
    with pytest.raises(ValueError):
        _executor.compile(net, invalid_img1, img2)
    with pytest.raises(TypeError):
    with pytest.raises(ValueError):
        _executor.compile(net, img1, invalid_img2)
    with pytest.raises(TypeError):
    with pytest.raises(ValueError):
        _executor.compile(net, invalid_img1, invalid_img2)
--- a/tests/ut/python/pipeline/infer/test_auto_monad.py
+++ b/tests/ut/python/pipeline/infer/test_auto_monad.py
@@ -186,6 +186,7 @@ def test_user_defined_bad_bprop():


 # shoul compile success and Print in presented in the final function graph.
@pytest.mark.skip(reason="isolated nodes exception")
 def test_unused_var():
    class UnusedVar(nn.Cell):
        def __init__(self):
@@ -211,6 +212,7 @@ def test_unused_var():


 # shoul compile success and Print in presented in the final function graph.
@pytest.mark.skip(reason="isolated nodes exception")
 def test_hof_unused_var():
    class UnusedVar(nn.Cell):
        def __init__(self):
@@ -239,6 +241,7 @@ def test_hof_unused_var():


 # shoul compile success and Print in presented in the final function graph.
@pytest.mark.skip(reason="isolated nodes exception")
 def test_partial_hof_unused_var():
    class UnusedVar(nn.Cell):
        def __init__(self):