Fix code check

4 years ago · ed0dab4497
--- a/ge/common/debug/memory_dumper.cc
+++ b/ge/common/debug/memory_dumper.cc
@@ -139,7 +139,8 @@ int MemoryDumper::OpenFile(const char *filename) {
  GE_IF_BOOL_EXEC(
    -1 != path_split_pos, string prefix_path = std::string(filename).substr(0, path_split_pos);
    string last_path = std::string(filename).substr(path_split_pos, strlen(filename) - 1);
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(prefix_path.length() >= MMPA_MAX_PATH, return kInvalidFd, "Prefix path is too long!");
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(prefix_path.length() >= MMPA_MAX_PATH, return kInvalidFd,
                                   "Prefix path is too long!");
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(mmRealPath(prefix_path.c_str(), tmp_path, MMPA_MAX_PATH) != EN_OK, return kInvalidFd,
                                   "Dir %s does not exit.", prefix_path.c_str());
    real_path = std::string(tmp_path) + last_path;)
--- a/ge/common/helper/model_helper.cc
+++ b/ge/common/helper/model_helper.cc
@@ -120,11 +120,11 @@ Status ModelHelper::SaveModelTbeKernel(std::shared_ptr<OmFileSaveHelper> &om_fil
  TBEKernelStore tbe_kernel_store = ge_model->GetTBEKernelStore();
  GELOGD("TBE_KERNELS size is %zu", tbe_kernel_store.DataSize());
  if (tbe_kernel_store.DataSize() > 0) {
    GE_CHK_STATUS_RET(
        SaveModelPartition(om_file_save_helper, ModelPartitionType::TBE_KERNELS,
        ge_model->GetTBEKernelStore().Data(), 
        ge_model->GetTBEKernelStore().DataSize(), model_index), 
        "Add tbe kernel partition failed");
    GE_CHK_STATUS_RET(SaveModelPartition(om_file_save_helper, 
                                         ModelPartitionType::TBE_KERNELS,
                                         ge_model->GetTBEKernelStore().Data(), 
                                         ge_model->GetTBEKernelStore().DataSize(),
                                         model_index), "Add tbe kernel partition failed");
  }
  // no need to check value, DATA->NetOutput
  (void)tbe_kernel_store.Load(tbe_kernel_store.Data(), tbe_kernel_store.DataSize());
--- a/ge/executor/ge_executor.cc
+++ b/ge/executor/ge_executor.cc
@@ -639,7 +639,8 @@ Status GeExecutor::UnloadModel(uint32_t model_id) {
    return ACL_ERROR_GE_INTERNAL_ERROR;
  }

  std::shared_ptr<hybrid::HybridDavinciModel> hybrid_davinci_model = ModelManager::GetInstance()->GetHybridModel(model_id);
  std::shared_ptr<hybrid::HybridDavinciModel> hybrid_davinci_model =
      ModelManager::GetInstance()->GetHybridModel(model_id);
  if (hybrid_davinci_model != nullptr) {
    uint64_t session_id = hybrid_davinci_model->GetSessionId();
    VarManagerPool::Instance().RemoveVarManager(session_id);
--- a/ge/graph/build/memory/binary_block_mem_assigner.cc
+++ b/ge/graph/build/memory/binary_block_mem_assigner.cc
@@ -21,7 +21,7 @@
 namespace {
 const uint32_t kRangeCeilInterval = 2;
 const uint32_t kLogBase = 2;
 const int64_t kLargeBlockSize = 8 * 1024 * 1024;
 const int64_t kLargeBlockSize = 8388608;   // 8 * 1024 * 1024
 const int64_t kLargeBlockRangeSize = 10;
 }  // namespace

--- a/ge/graph/build/memory/block_mem_assigner.cc
+++ b/ge/graph/build/memory/block_mem_assigner.cc
@@ -1266,8 +1266,8 @@ Status BlockMemAssigner::AssignOutputMemoryWithReuse(const NodePtr &node, vector
    bool reset_zero_copy_flag = false;
    bool no_need_assign_memory = ((size == 0) || CheckIsZeroMemNodeType(node->GetType()));
    if (!no_need_assign_memory) {
      out_node_set_continuous_input =
          IsOutNodeSetContinuousInput(node, i, peer_name, peer_input_index, no_need_assign_memory, reset_zero_copy_flag);
      out_node_set_continuous_input = IsOutNodeSetContinuousInput(node, i, peer_name, peer_input_index,
                                                                  no_need_assign_memory, reset_zero_copy_flag);
      GE_IF_BOOL_EXEC(!no_need_assign_memory,
          no_need_assign_memory = IsAtomicOutputMemory(node, i, is_atomic, out_node_set_continuous_input););
    }
@@ -1349,7 +1349,7 @@ void BlockMemAssigner::AssignMemoryWithReuse(vector<int64_t> &ranges) {
      bool workspace_skip_flag = false;
      if (has_tvm_workspace_mem_type_attr && tvm_workspace_memory_type[i] == RT_MEMORY_L1) {
        GELOGI(
            "fusion: node[%s]workspace index[%zu] is not hbm type, add to zero_memory_list, workspace memory type [%ld]",
            "fusion: node[%s]workspace idx[%zu] is not hbm type, add to zero_memory_list, workspace memory type [%ld]",
            node_op_desc->GetName().c_str(), i, tvm_workspace_memory_type[i]);
        workspace_skip_flag = true;
      }
--- a/ge/graph/build/stream_allocator.cc
+++ b/ge/graph/build/stream_allocator.cc
@@ -49,7 +49,8 @@ inline bool HasContinuousStreamLabel(const ge::OpDescPtr &op_desc, std::string &
 }

 bool IsHcclOp(const string &op_type) {
  const set<string> hccl_op_types({ge::HCOMBROADCAST, ge::HCOMALLGATHER, ge::HCOMALLREDUCE, ge::HCOMREDUCESCATTER, ge::HCOMREDUCE});
  const set<string> hccl_op_types({ge::HCOMBROADCAST, ge::HCOMALLGATHER, ge::HCOMALLREDUCE, ge::HCOMREDUCESCATTER,
                                   ge::HCOMREDUCE});
  return hccl_op_types.find(op_type) != hccl_op_types.end();
 }
 }  // namespace
--- a/ge/graph/load/new_model_manager/davinci_model.cc
+++ b/ge/graph/load/new_model_manager/davinci_model.cc
@@ -83,7 +83,7 @@ const uint32_t kAddrLen = sizeof(void *);
 const int kDecimal = 10;
 const int kBytes = 8;
 const uint32_t kDataMemAlignSizeCompare = 64;
 const uint32_t kDumpL1FusionOpMByteSize = 2 * 1024 * 1024;
 const uint32_t kDumpL1FusionOpMByteSize = 2097152;   // 2 * 1024 * 1024
 const uint32_t kDumpFlagOfL1Fusion = 0;
 const char *const kDefaultBatchLable = "Batch_default";
 const char *const kGetDynamicDimsName = "ascend_mbatch_get_dynamic_dims_node";
@@ -330,8 +330,8 @@ Status DavinciModel::InitFeatureMapAndP2PMem(void *dev_ptr, size_t mem_size) {
      GELOGE(GE_EXEC_ALLOC_FEATURE_MAP_MEM_FAILED, "Alloc feature map memory failed. size: %zu", data_size);
      return GE_EXEC_ALLOC_FEATURE_MAP_MEM_FAILED;
    }
    GEEVENT("[IMAS]InitFeatureMapAndP2PMem graph_%u MallocMemory type[F] memaddr[%p] mem_size[%zu]", runtime_param_.graph_id,
            mem_base_, data_size);
    GEEVENT("[IMAS]InitFeatureMapAndP2PMem graph_%u MallocMemory type[F] memaddr[%p] mem_size[%zu]", 
            runtime_param_.graph_id, mem_base_, data_size);

    if (!is_inner_weight_base_) {
      weights_mem_base_ = mem_base_;
@@ -1543,7 +1543,8 @@ Status DavinciModel::LoadWithQueue() {
  }

  if (output_queue_ids_.size() != new_output_data_info_.size()) {
    GELOGE(ACL_ERROR_GE_EXEC_MODEL_QUEUE_ID_INVALID, "Output queue ids not match model: output_queue=%zu output_data=%zu",
    GELOGE(ACL_ERROR_GE_EXEC_MODEL_QUEUE_ID_INVALID, 
           "Output queue ids not match model: output_queue=%zu output_data=%zu",
           output_queue_ids_.size(), new_output_data_info_.size());
    return ACL_ERROR_GE_EXEC_MODEL_QUEUE_ID_INVALID;
  }
@@ -4061,7 +4062,7 @@ void DavinciModel::SetDataDumperArgs(const ComputeGraphPtr &compute_graph) {
  data_dumper_.SetDeviceId(device_id);

  // set loop count addr
  auto get_var_addr = [](const OpDescPtr &op, const RuntimeParam &runtime_param) -> void * {
  auto get_var_addr = [](const OpDescPtr &op, const RuntimeParam &runtime_param) -> void* {
    if (op != nullptr) {
      auto v_output_size = ModelUtils::GetOutputSize(op);
      auto v_output_addr = ModelUtils::GetOutputDataAddrs(runtime_param, op);
--- a/ge/graph/manager/graph_manager.cc
+++ b/ge/graph/manager/graph_manager.cc
@@ -550,7 +550,8 @@ Status GraphManager::OptimizeSubGraphWithMultiThreads(ComputeGraphPtr compute_gr
      (void) AttrUtils::SetStr(subgraph->GetSubGraph(), ATTR_NAME_OP_COMPILE_STRATEGY, op_compile_strategy);
    }
    std::future<Status> f = executor.commit(GraphManager::ProcessSubGraphWithMultiThreads, this,
                                            compute_graph->GetGraphID(), subgraph, compute_graph, session_id, GetThreadLocalContext());
                                            compute_graph->GetGraphID(), subgraph, compute_graph, 
                                            session_id, GetThreadLocalContext());
    if (!f.valid()) {
      GELOGE(FAILED, "Future is invalid");
      return FAILED;
--- a/ge/graph/manager/util/debug.cc
+++ b/ge/graph/manager/util/debug.cc
@@ -32,7 +32,8 @@ Debug::~Debug() = default;

 void Debug::DumpProto(const Message &proto, const char *file) {
  std::string file_path = RealPath(file);
  int fd = mmOpen2(file_path.c_str(), M_WRONLY | M_CREAT | O_TRUNC, M_IRUSR | M_IWUSR | M_UMASK_GRPREAD | M_UMASK_OTHREAD);
  int fd = mmOpen2(file_path.c_str(), M_WRONLY | M_CREAT | O_TRUNC, M_IRUSR | M_IWUSR | M_UMASK_GRPREAD | 
                   M_UMASK_OTHREAD);
  if (fd == -1) {
    GELOGW("Write %s failed", file_path.c_str());
    return;
--- a/ge/graph/passes/subgraph_pass.cc
+++ b/ge/graph/passes/subgraph_pass.cc
@@ -150,7 +150,8 @@ Status SubgraphPass::SubgraphOutputNode(const ComputeGraphPtr &graph, const Node
    std::string op_type;
    bool insert_flag = NodeUtils::GetConstOpType(in_node, op_type) ||
                       IsAtomicRequired(in_node, peer_out_anchor->GetIdx()) || IsOutputContinuesRequired(in_node) ||
                       ((in_node->GetType() == DATA) && (kWhileOpTypes.count(graph->GetParentNode()->GetType()) == 0)) ||
                       ((in_node->GetType() == DATA) && 
                        (kWhileOpTypes.count(graph->GetParentNode()->GetType()) == 0)) ||
                       (!graph->GetGraphUnknownFlag() && NodeUtils::IsDynamicShape(node) &&
                        (kWhileOpTypes.count(in_node->GetType()) != 0));
    if (insert_flag) {
--- a/ge/graph/preprocess/graph_preprocess.cc
+++ b/ge/graph/preprocess/graph_preprocess.cc
@@ -1621,7 +1621,8 @@ Status GraphPrepare::CheckUserInput(const std::vector<GeTensor> &user_input) {

      for (size_t i = 0; i < desc.GetShape().GetDimNum(); ++i) {
        if (desc.GetShape().GetDim(i) < 0) {
          std::string situation = "data dim[" + std::to_string(i) + "][" + std::to_string(desc.GetShape().GetDim(i)) + "]" ;
          std::string situation = "data dim[" + std::to_string(i) + "][" + std::to_string(desc.GetShape().GetDim(i)) + 
                                  "]";
          std::string reason = "it need >= 0";
          ErrorManager::GetInstance().ATCReportErrMessage("E19025", {"situation", "reason"}, {situation, reason});
          GELOGE(GE_GRAPH_INIT_FAILED, "data dim %zu is not supported, need >= 0, real:%ld.", i,
--- a/ge/host_kernels/ssd_prior_box_kernel.cc
+++ b/ge/host_kernels/ssd_prior_box_kernel.cc
@@ -180,9 +180,9 @@ Status SsdPriorboxKernel::SetVariance(const vector<float> &variance, const int d
  return SUCCESS;
 }

 Status SsdPriorboxKernel::GetNumPriorAndDimSize(uint32_t aspect_ratios_size, uint32_t min_sizes_size, uint32_t max_sizes_size,
                                                int layer_width, int layer_height, int &num_priors,
                                                int &dim_size) const {
 Status SsdPriorboxKernel::GetNumPriorAndDimSize(uint32_t aspect_ratios_size, uint32_t min_sizes_size, 
                                                uint32_t max_sizes_size, int layer_width, int layer_height,
                                                int &num_priors, int &dim_size) const {
  if (ge::CheckUint32MulOverflow(min_sizes_size, aspect_ratios_size) != SUCCESS) {
    return PARAM_INVALID;
  }
--- a/ge/hybrid/executor/hybrid_model_async_executor.cc
+++ b/ge/hybrid/executor/hybrid_model_async_executor.cc
@@ -379,11 +379,13 @@ Status HybridModelAsyncExecutor::Execute(const std::vector<DataBuffer> &inputs,
    }
    if (output_real_size > 0) {
      if (outputs[i].length < static_cast<uint64_t>(output_real_size)) {
        GELOGE(FAILED, "output idx[%zu], the memory size of output[%lu] given by user should be greater than or equal to the real size of output[%ld]",
        GELOGE(FAILED, 
               "output idx[%zu], the memory size of output[%lu] given by user should >= the real size of output[%ld]",
               i, outputs[i].length, output_real_size);
        return FAILED;
      }
      GE_CHK_RT_RET(rtMemcpy(outputs[i].data, outputs[i].length, args.outputs[i].GetData(), output_real_size, RT_MEMCPY_DEVICE_TO_DEVICE));
      GE_CHK_RT_RET(rtMemcpy(outputs[i].data, outputs[i].length, args.outputs[i].GetData(), output_real_size, 
                    RT_MEMCPY_DEVICE_TO_DEVICE));
    }
    outputs[i].length = output_real_size;
  }
--- a/ge/hybrid/executor/worker/shape_inference_engine.cc
+++ b/ge/hybrid/executor/worker/shape_inference_engine.cc
@@ -62,7 +62,8 @@ Status ShapeInferenceEngine::InferShape(NodeState &node_state) {
  {
    std::lock_guard<std::mutex> lk(mu_);
    RECORD_SHAPE_INFERENCE_EVENT(execution_context_, node_item.NodeName().c_str(), "[InferShapeAndType] Start");
    GE_CHK_STATUS_RET(ShapeRefiner::InferShapeAndTypeForRunning(node_item.node, true), "Invoke InferShapeAndType failed.");
    GE_CHK_STATUS_RET(ShapeRefiner::InferShapeAndTypeForRunning(node_item.node, true), 
                      "Invoke InferShapeAndType failed.");
    RECORD_SHAPE_INFERENCE_EVENT(execution_context_, node_item.NodeName().c_str(), "[InferShapeAndType] End");
  }
  // Check again to make sure shape is valid after shape inference
--- a/ge/hybrid/model/hybrid_model.cc
+++ b/ge/hybrid/model/hybrid_model.cc
@@ -176,7 +176,8 @@ Status HybridModel::GetInputOutputDescInfo(vector<InputOutputDescInfo> &input_de
  return SUCCESS;
 }

 void HybridModel::SetInputDimsAndShapeRangesInfo(const vector<int64_t> &model_input_dims, std::vector<std::pair<int64_t,int64_t>> &shape_ranges,
 void HybridModel::SetInputDimsAndShapeRangesInfo(const vector<int64_t> &model_input_dims, 
                                                 std::vector<std::pair<int64_t, int64_t>> &shape_ranges,
                                                 InputOutputDescInfo &input) {
  for (auto model_input_dim : model_input_dims) {
    input.shape_info.dims.push_back(model_input_dim);
@@ -245,7 +246,9 @@ Status HybridModel::GetInputDescInfo(vector<InputOutputDescInfo> &input_desc, st
  return SUCCESS;
 }

 void HybridModel::CreateOutput(ConstGeTensorDescPtr &output_desc, InputOutputDescInfo &output_desc_info, uint32_t &format_result) {
 void HybridModel::CreateOutput(ConstGeTensorDescPtr &output_desc, 
                               InputOutputDescInfo &output_desc_info, 
                               uint32_t &format_result) {
  GE_IF_BOOL_EXEC(output_desc == nullptr, GELOGE(FAILED, "output desc ptr is nullptr"); return );
  Format format = output_desc->GetFormat();
  GeShape shape = output_desc->GetShape();
@@ -283,7 +286,8 @@ void HybridModel::CreateOutput(ConstGeTensorDescPtr &output_desc, InputOutputDes

 Status HybridModel::GetOutputDescInfo(vector<InputOutputDescInfo> &output_desc, std::vector<uint32_t> &formats) {
  std::vector<ConstGeTensorDescPtr> output_desc_list;
  GE_CHK_STATUS_RET(root_graph_item_->GetOutputDescList(output_desc_list), "get output desc info failed");  // output_desc_list contains vaild input desc
  GE_CHK_STATUS_RET(root_graph_item_->GetOutputDescList(output_desc_list), 
                    "get output desc info failed");  // output_desc_list contains vaild input desc

  vector<std::string> out_node_names;
  (void)ge::AttrUtils::GetListStr(ge_root_model_->GetRootGraph(), ATTR_MODEL_OUT_NODES_NAME, out_node_names);
@@ -293,7 +297,8 @@ Status HybridModel::GetOutputDescInfo(vector<InputOutputDescInfo> &output_desc,
  GE_CHECK_NOTNULL(op_desc);

  auto out_size = static_cast<uint32_t>(op_desc->GetInputsSize());
  GE_CHK_BOOL_RET_STATUS(out_size == output_desc_list.size(), FAILED, "output size[%u] not match output_desc_list size[%zu]", out_size, output_desc_list.size());
  GE_CHK_BOOL_RET_STATUS(out_size == output_desc_list.size(), FAILED,
                         "output size[%u] not match output_desc_list size[%zu]", out_size, output_desc_list.size());

  for (uint32_t index = 0; index < out_size; ++index) {
    string output_name;
@@ -301,9 +306,11 @@ Status HybridModel::GetOutputDescInfo(vector<InputOutputDescInfo> &output_desc,
    std::vector<int64_t> src_index = op_desc->GetSrcIndex();
    if (out_size == out_node_names.size()) {
      bool contains_colon = out_node_names[index].find(":") != std::string::npos;
      output_name = contains_colon ? out_node_names[index] : out_node_names[index] + ":" + std::to_string(src_index[index]);
      output_name = contains_colon ? out_node_names[index] : out_node_names[index] + ":" +
                    std::to_string(src_index[index]);
    } else {
      output_name = std::string("output_") + std::to_string(index) + "_" + src_name[index] + "_" + std::to_string(src_index[index]);
      output_name = std::string("output_") + std::to_string(index) + "_" + src_name[index] + "_" +
                    std::to_string(src_index[index]);
    }

    InputOutputDescInfo output_desc_info;
--- a/ge/opskernel_manager/ops_kernel_manager.cc
+++ b/ge/opskernel_manager/ops_kernel_manager.cc
@@ -175,8 +175,8 @@ Status OpsKernelManager::ParsePluginOptions(const map<string, string> &options,
      } else if (flag == 1) {
        enable_flag = true;
      } else {
        GELOGE(GE_GRAPH_OPTIONS_INVALID, "option_key:%s, its value %s is invalid, it must be 0 or 1.", plugin_name.c_str(),
               iter->second.c_str());
        GELOGE(GE_GRAPH_OPTIONS_INVALID, "option_key:%s, its value %s is invalid, it must be 0 or 1.", 
               plugin_name.c_str(), iter->second.c_str());
        return GE_GRAPH_OPTIONS_INVALID;
      }
    } catch (std::invalid_argument &) {
@@ -188,7 +188,8 @@ Status OpsKernelManager::ParsePluginOptions(const map<string, string> &options,
             iter->second.c_str());
      return GE_GRAPH_OPTIONS_INVALID;
    } catch (...) {
      GELOGE(GE_GRAPH_OPTIONS_INVALID, "option_key:%s, its value %s is invalid, it must be 0 or 1.", plugin_name.c_str(),
      GELOGE(GE_GRAPH_OPTIONS_INVALID, "option_key:%s, its value %s is invalid, it must be 0 or 1.",
             plugin_name.c_str(),
             iter->second.c_str());
      return GE_GRAPH_OPTIONS_INVALID;
    }
--- a/ge/session/omg.cc
+++ b/ge/session/omg.cc
@@ -644,7 +644,8 @@ Status ParseOutNodes(const string &out_nodes) {
        if (!domi::GetContext().user_out_nodes_top_vec.empty()) {
          ErrorManager::GetInstance().ATCReportErrMessage("E10001", {"parameter", "value", "reason"},
                                                          {"--out_nodes", out_nodes, "is not all index or top_name"});
          GELOGE(PARAM_INVALID, "This out_nodes str must be all index or top_name, while the actual input is %s", out_nodes.c_str());
          GELOGE(PARAM_INVALID, "This out_nodes str must be all index or top_name, while the actual input is %s",
                 out_nodes.c_str());
          return PARAM_INVALID;
        }
        // stoi: The method may throw an exception: invalid_argument/out_of_range
--- a/ge/single_op/single_op.cc
+++ b/ge/single_op/single_op.cc
@@ -109,7 +109,8 @@ Status SingleOp::ValidateArgs(const std::vector<DataBuffer> &inputs, const std::

  auto num_outputs = outputs.size();
  if (num_outputs != output_sizes_.size()) {
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "output num mismatch. model expect %zu, but given %zu", output_sizes_.size(), outputs.size());
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "output num mismatch. model expect %zu, but given %zu", 
           output_sizes_.size(), outputs.size());
    return ACL_ERROR_GE_PARAM_INVALID;
  }

@@ -248,12 +249,14 @@ Status DynamicSingleOp::ValidateParams(const vector<GeTensorDesc> &input_desc,
  }

  if (input_desc.size() != num_inputs_) {
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Input number mismatches. expect %zu, but given %zu", num_inputs_, input_desc.size());
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Input number mismatches. expect %zu, but given %zu", num_inputs_, 
           input_desc.size());
    return ACL_ERROR_GE_PARAM_INVALID;
  }

  if (output_desc.size() != num_outputs_) {
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Output number mismatches. expect %zu, but given %zu", num_outputs_, output_desc.size());
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Output number mismatches. expect %zu, but given %zu", num_outputs_, 
           output_desc.size());
    return ACL_ERROR_GE_PARAM_INVALID;
  }

--- a/ge/single_op/single_op_model.cc
+++ b/ge/single_op/single_op_model.cc
@@ -263,7 +263,8 @@ Status SingleOpModel::BuildTaskList(SingleOp &single_op) {
        task->SetModelArgs(model_name_, model_id_);
        single_op.tasks_.emplace_back(task);
      } else {
        GELOGE(ACL_ERROR_GE_OP_KERNEL_TYPE_INVALID, "Only TBE, AI_CPU, CUST_AI_CPU kernel are supported, but got %u", context.kernel_type());
        GELOGE(ACL_ERROR_GE_OP_KERNEL_TYPE_INVALID, "Only TBE, AI_CPU, CUST_AI_CPU kernel are supported, but got %u",
               context.kernel_type());
        return ACL_ERROR_GE_OP_KERNEL_TYPE_INVALID;
      }
    } else if (task_type == RT_MODEL_TASK_KERNEL_EX) {
--- a/ge/single_op/task/tbe_task_builder.cc
+++ b/ge/single_op/task/tbe_task_builder.cc
@@ -173,7 +173,8 @@ Status TbeTaskBuilder::RegisterKernel(TbeOpTask &task, const SingleOpModelParam

    auto tbe_kernel = GetTbeKernel(op_desc_);
    if (tbe_kernel == nullptr) {
      GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "OP EXT ATTR NAME TBE_KERNEL not found. op = %s", op_desc_->GetName().c_str());
      GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "OP EXT ATTR NAME TBE_KERNEL not found. op = %s",
             op_desc_->GetName().c_str());
      return ACL_ERROR_GE_INTERNAL_ERROR;
    }

--- a/inc/framework/common/taskdown_common.h
+++ b/inc/framework/common/taskdown_common.h
@@ -21,7 +21,7 @@

 namespace ge {

 #define CC_FUSION_OP_MAX 32
 const int CC_FUSION_OP_MAX = 32;

 typedef enum tagCcStatus {
  CC_STATUS_SUCCESS = 0,         /**< succ */