Pre Merge pull request !2039 from guopeian/aicpu-four-op

3 years ago · e852c8b4a2
--- a/ge/hybrid/node_executor/aicpu/aicpu_node_executor.cc
+++ b/ge/hybrid/node_executor/aicpu/aicpu_node_executor.cc
@@ -441,8 +441,8 @@ Status AicpuTfNodeTask::EnsureSessionCreated(uint64_t session_id) {
  return SUCCESS;
 }

 Status AicpuTfNodeTask::ReadResultSummaryAndPrepareMemory(TaskContext &context,
                                                          std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
 Status AicpuNodeTaskBase::ReadResultSummaryAndPrepareMemory(TaskContext &context,
                                                            std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
  for (auto i = 0; i < node_item_->num_outputs; ++i) {
    auto &result_summary = output_summary_host_[i];
    GE_CHK_RT_RET(rtMemcpy(&result_summary, sizeof(aicpu::FWKAdapter::ResultSummary),
@@ -467,6 +467,30 @@ Status AicpuTfNodeTask::ReadResultSummaryAndPrepareMemory(TaskContext &context,
  return SUCCESS;
 }

 Status AicpuNodeTask::CopyDataToHbm(TaskContext &context,
                                    const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
  GE_CHK_BOOL_RET_STATUS(out_shape_hbm.size() == static_cast<std::size_t>(node_item_->num_outputs),
                         INTERNAL_ERROR,
                         "[Check][Size]Node[%s] has %d outputs but out shape is %zu not equal.",
                         node_name_.c_str(), node_item_->num_outputs, out_shape_hbm.size());

  GE_CHK_STATUS_RET_NOLOG(PrepareCopyInputs(context, out_shape_hbm));

  RECORD_CALLBACK_EVENT(context.GetExecutionContext(), node_name_.c_str(), "[LaunchCopy] Start");
  auto rt_ret = rtCpuKernelLaunchWithFlag(reinterpret_cast<const void *>(memcpy_so_name_.c_str()),
                                          reinterpret_cast<const void *>(memcpy_kernel_name_.c_str()),
                                          1, // default core dim is 1
                                          memcpy_args_.get(), memcpy_args_size_,
                                          nullptr, context.GetStream(), RT_KERNEL_DEFAULT);
  GE_CHK_RT_RET(rt_ret);

  RECORD_CALLBACK_EVENT(context.GetExecutionContext(), node_name_.c_str(), "[LaunchCopy] End");

  GE_CHK_RT_RET(rtStreamSynchronize(context.GetStream()));
  RECORD_CALLBACK_EVENT(context.GetExecutionContext(), node_name_.c_str(), "[SynchronizeCopy] End");
  return SUCCESS;
 }

 Status AicpuTfNodeTask::CopyDataToHbm(TaskContext &context,
                                      const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
  GE_CHK_BOOL_RET_STATUS(out_shape_hbm.size() == static_cast<std::size_t>(node_item_->num_outputs),
@@ -486,8 +510,8 @@ Status AicpuTfNodeTask::CopyDataToHbm(TaskContext &context,
  return SUCCESS;
 }

 Status AicpuTfNodeTask::PrepareCopyInputs(const TaskContext &context,
                                          const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
 Status AicpuNodeTaskBase::PrepareCopyInputs(const TaskContext &context,
                                            const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
  std::vector<uint64_t> copy_input_release_flag;
  std::vector<uint64_t> copy_input_data_size;
  std::vector<uint64_t> copy_input_src;
@@ -528,8 +552,8 @@ Status AicpuTfNodeTask::PrepareCopyInputs(const TaskContext &context,
  return SUCCESS;
 }

 Status AicpuTfNodeTask::UpdateShapeByHbmBuffer(TaskContext &context,
                                               const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
 Status AicpuNodeTaskBase::UpdateShapeByHbmBuffer(TaskContext &context,
                                                 const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) {
  GE_CHK_BOOL_RET_STATUS(out_shape_hbm.size() == static_cast<std::size_t>(node_item_->num_outputs),
                         INTERNAL_ERROR,
                         "Node[%s] has %d outputs but out shape is %zu",
@@ -560,7 +584,7 @@ Status AicpuTfNodeTask::UpdateShapeByHbmBuffer(TaskContext &context,
  return SUCCESS;
 }

 Status AicpuTfNodeTask::UpdateShapeAndDataByResultSummary(TaskContext &context) {
 Status AicpuNodeTaskBase::UpdateShapeAndDataByResultSummary(TaskContext &context) {
  GELOGD("Node[%s] update shape and data by result summary begin.", node_name_.c_str());

  std::vector<std::unique_ptr<TensorBuffer>> out_shape_hbm;
@@ -649,7 +673,7 @@ Status AicpuTfNodeTask::LaunchTask(TaskContext &context) {
  return SUCCESS;
 }

 Status AicpuTfNodeTask::TaskCallback(TaskContext &context) {
 Status AicpuNodeTaskBase::TaskCallback(TaskContext &context) {
  GELOGD("Node[%s] task callback start. is_dynamic=%s, unknown_type=%d.",
         node_name_.c_str(), node_item_->is_dynamic ? "true" : "false", unknown_type_);
  Status callback_ret = SUCCESS;
@@ -666,14 +690,115 @@ Status AicpuTfNodeTask::TaskCallback(TaskContext &context) {
  return callback_ret;
 }

 Status AicpuNodeTask::SetMemCopyTask(const domi::TaskDef &task_def) {
  if (node_item_->num_outputs == 0) {
    GELOGD("Node[%s] type[%s] has no output, no need set mem_copy task.",
           node_name_.c_str(), node_item_->node_type.c_str());
    return SUCCESS;
  }

  GELOGD("Start to set memcpy task for node[%s].", node_name_.c_str());
  const domi::KernelDef &kernel_def = task_def.kernel();
  auto &memcpy_args = kernel_def.args();
  memcpy_args_size_ = kernel_def.args_size();
  memcpy_so_name_ = kernel_def.so_name();
  memcpy_kernel_name_ = kernel_def.kernel_name();
  if (memcpy_args.size() != memcpy_args_size_) {
    REPORT_INNER_ERROR("E19999", "MemCopy task def args.size=%zu, but args_size=%u not equal.",
                       memcpy_args.size(), memcpy_args_size_);
    GELOGE(FAILED, "[Check][Size]MemCopy task def args.size=%zu, but args_size=%u not equal.",
           memcpy_args.size(), memcpy_args_size_);
    return FAILED;
  }

  if (memcpy_args_size_ < sizeof(aicpu::AicpuParamHead)) {
    REPORT_INNER_ERROR("E19999", "Task def args_size=%u is less than aicpu param head len=%zu.",
                       memcpy_args_size_, sizeof(aicpu::AicpuParamHead));
    GELOGE(FAILED, "[Check][Size] Task def args_size=%u is less than aicpu param head len=%zu.",
           memcpy_args_size_, sizeof(aicpu::AicpuParamHead));
    return FAILED;
  }

  memcpy_args_.reset(new(std::nothrow) uint8_t[memcpy_args_size_]());
  if (memcpy_args_ == nullptr) {
    REPORT_INNER_ERROR("E19999", "new memory failed for Node[MemCopy], task_size[%u].",
                       memcpy_args_size_);
    GELOGE(FAILED, "[Malloc][Memory] failed for Node[MemCopy], task_size[%u].",
           memcpy_args_size_);
    return FAILED;
  }

  errno_t sec_ret = memcpy_s(memcpy_args_.get(), memcpy_args_size_, memcpy_args.c_str(), memcpy_args.size());
  if (sec_ret != EOK) {
    REPORT_INNER_ERROR("E19999",
                       "memcpy_s argc_ failed for Node[MemCopy], ret: %d", sec_ret);
    GELOGE(INTERNAL_ERROR,
           "[Update][args] failed for Node[MemCopy], ret: %d", sec_ret);
    return sec_ret;
  }

  auto memcpy_param_head = reinterpret_cast<aicpu::AicpuParamHead *>(memcpy_args_.get());
  uint32_t memcpy_io_num = memcpy_param_head->ioAddrNum;
  auto memcpy_io_addr = memcpy_args_.get() + sizeof(aicpu::AicpuParamHead);
  // if has input and output, need copy to ioaddr
  int cpy_ret = memcpy_s(memcpy_io_addr, memcpy_args_size_ - sizeof(aicpu::AicpuParamHead),
                         &copy_io_addr_[0], sizeof(uint64_t) * memcpy_io_num);
  if (cpy_ret != 0) {
    REPORT_INNER_ERROR("E19999", "Node[Memcpoy] memcpy io addr to AicpuParamHead failed,"
                       "ret=%d, args_size=%u, io nums=%u.",
                       cpy_ret, memcpy_args_size_, memcpy_io_num);
    GELOGE(INTERNAL_ERROR, "[Update][io_addr]Node[MemCopy] memcpy io addr to AicpuParamHead failed,"
           "ret=%d, args_size=%u, io nums=%u.",
           cpy_ret, memcpy_args_size_, memcpy_io_num);
    return INTERNAL_ERROR;
  }
  GELOGD("Set memcpy task for node[MemCopy] successfully.");
  return SUCCESS;
 }

 Status AicpuNodeTask::InitForDependComputeTask() {
  if ((unknown_type_ != DEPEND_COMPUTE) || (node_item_->num_outputs == 0)) {
    GELOGD("Node[%s] type[%s] unknown_type is %d, output num is %d.",
           node_name_.c_str(), node_item_->node_type.c_str(), unknown_type_, node_item_->num_outputs);
    return SUCCESS;
  }

  output_summary_.resize(node_item_->num_outputs);
  constexpr auto result_summary_size = sizeof(aicpu::FWKAdapter::ResultSummary);
  for (auto i = 0; i < node_item_->num_outputs; ++i) {
    GE_CHK_STATUS_RET(AllocTensorBuffer(result_summary_size, output_summary_[i]),
                      "[Alloc][TensorBuffer] failed for Node[%s] to copy result summary info, size=%zu.",
                      node_name_.c_str(), result_summary_size);
  }
  output_summary_host_.resize(node_item_->num_outputs);

  // init for mem copy task
  // copy task need copy output_data and output_shape, max len is 2 * output_num
  const size_t copy_input_buf_len = node_item_->num_outputs * 2 * sizeof(uint64_t);
  GE_CHK_STATUS_RET(AllocTensorBuffer(copy_input_buf_len, copy_input_release_flag_dev_),
                    "[Alloc][TensorBuffer] failed for Node[%s] to copy task input release_flag, size=%zu",
                    node_name_.c_str(), copy_input_buf_len);
  GE_CHK_STATUS_RET(AllocTensorBuffer(copy_input_buf_len, copy_input_data_size_dev_),
                    "[Alloc][TensorBuffer] failed for Node[%s] to copy task input data_size, size=%zu",
                    node_name_.c_str(), copy_input_buf_len);
  GE_CHK_STATUS_RET(AllocTensorBuffer(copy_input_buf_len, copy_input_src_dev_),
                    "[Alloc][TensorBuffer] failed for Node[%s] to copy task input src, size=%zu",
                    node_name_.c_str(), copy_input_buf_len);
  GE_CHK_STATUS_RET(AllocTensorBuffer(copy_input_buf_len, copy_input_dst_dev_),
                    "[Alloc][TensorBuffer] failed for Node[%s] to copy task input dst, size=%zu",
                    node_name_.c_str(), copy_input_buf_len);

  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_release_flag_dev_->GetData()));
  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_data_size_dev_->GetData()));
  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_src_dev_->GetData()));
  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_dst_dev_->GetData()));
  return SUCCESS;
 }

 Status AicpuNodeTask::Init(const HybridModel &model) {
  auto node_name = node_name_;
  GELOGD("Node[%s] init start.", node_name.c_str());

  GE_CHK_BOOL_RET_STATUS(unknown_type_ != DEPEND_COMPUTE, FAILED,
                         "[Check][Type]Node[%s] unknown type[%d] is depend compute, it's not supported now.",
                         node_name.c_str(), unknown_type_);

  GE_CHK_BOOL_RET_STATUS(task_def_.has_kernel(), FAILED,
                         "[Check][task_def_]Node[%s] task def does not has kernel.", node_name.c_str());
  auto &kernel_def = task_def_.kernel();
@@ -762,7 +887,10 @@ Status AicpuNodeTask::Init(const HybridModel &model) {
  uint64_t ext_session_id = model.GetSessionId();
  GE_CHK_STATUS_RET(InitExtInfo(kernel_ext_info, ext_session_id),
                    "[Init][ExtInfo] failed for Node[%s].", node_name.c_str());

  
  GE_CHK_STATUS_RET(InitForDependComputeTask(),
                    "[Init][DependComputeTask] failed for Node[%s].",
                    node_name_.c_str());
  if (ext_info_addr_dev_ == nullptr) {
    aicpu_param_head->extInfoLength = 0;
    aicpu_param_head->extInfoAddr = 0;
@@ -770,7 +898,11 @@ Status AicpuNodeTask::Init(const HybridModel &model) {
    aicpu_param_head->extInfoLength = ext_info_addr_dev_->GetSize();
    aicpu_param_head->extInfoAddr = reinterpret_cast<uintptr_t>(ext_info_addr_dev_->GetData());
  }

  auto task_defs = model.GetTaskDefs(node_item_->node);
  GE_CHECK_NOTNULL(task_defs);
  if (unknown_type_ == DEPEND_COMPUTE) {
    GE_CHK_STATUS_RET_NOLOG(SetMemCopyTask((*task_defs)[1]));
  }
  GELOGD("Node[%s] init end.", node_name.c_str());
  return SUCCESS;
 }
@@ -786,13 +918,29 @@ Status AicpuNodeTask::UpdateIoAddr(TaskContext &context) {
    io_addrs.emplace_back(reinterpret_cast<uintptr_t>(inputData->GetData()));
  }

  GE_CHK_STATUS_RET_NOLOG(context.AllocateOutputs());
  for (auto j = 0; j < node_item_->num_outputs; ++j) {
    auto outputData = context.GetOutput(j);
    GE_CHECK_NOTNULL(outputData);
    GELOGD("Node[%s] output[%d] addr = %p, size = %zu", node_name_.c_str(), j,
           outputData->GetData(), outputData->GetSize());
    io_addrs.emplace_back(reinterpret_cast<uintptr_t>(outputData->GetData()));
  // known shape or not depend compute
  if (!node_item_->is_dynamic || unknown_type_ != DEPEND_COMPUTE) {
    // unknown type 4 do this in call back.
    GE_CHK_STATUS_RET_NOLOG(context.AllocateOutputs());
    for (auto j = 0; j < node_item_->num_outputs; ++j) {
      auto outputData = context.GetOutput(j);
      GE_CHECK_NOTNULL(outputData);
      GELOGD("Node[%s] output[%d] addr = %p, size = %zu",
             node_name_.c_str(), j, outputData->GetData(), outputData->GetSize());
      io_addrs.emplace_back(reinterpret_cast<uintptr_t>(outputData->GetData()));
    }
  } else {
    // unknown type 4 use result summary update ioaddr.
    GELOGD("Node[%s] is depend compute node, use result summary as out addr.", node_name_.c_str());
    GE_CHK_BOOL_RET_STATUS(output_summary_.size() == static_cast<std::size_t>(node_item_->num_outputs),
                           INTERNAL_ERROR,
                           "[Check][Size]Node[%s] has %d output but %zu output summary not equal.",
                           node_name_.c_str(), node_item_->num_outputs, output_summary_.size());

    for (auto j = 0; j < node_item_->num_outputs; ++j) {
      void *summary_addr = output_summary_[j]->GetData();
      io_addrs.emplace_back(reinterpret_cast<uintptr_t>(summary_addr));
    }
  }

  auto io_addr = args_.get() + sizeof(aicpu::AicpuParamHead);
@@ -830,23 +978,6 @@ Status AicpuNodeTask::LaunchTask(TaskContext &context) {
  return SUCCESS;
 }

 Status AicpuNodeTask::TaskCallback(TaskContext &context) {
  GELOGD("Node[%s] task callback start, is_dynamic = %s, unknown_type=%d.",
         node_name_.c_str(), node_item_->is_dynamic ? "true" : "false", unknown_type_);
  Status callback_ret = SUCCESS;

  // check need update shape, call update shape.
  if (node_item_->is_dynamic && unknown_type_ == DEPEND_SHAPE_RANGE) {
    // check result
    callback_ret = UpdateOutputShapeFromExtInfo(context);
  } else {
    GELOGD("Node[%s] unknown shape type is %d no need update output shape.",
           node_name_.c_str(), unknown_type_);
  }
  GELOGD("Node[%s] task callback end.", node_name_.c_str());
  return callback_ret;
 }

 Status AiCpuNodeExecutor::PrepareTask(NodeTask &task, TaskContext &context) const {
  // malloc HBM memory at Init, here just update them
  RECORD_EXECUTION_EVENT(context.GetExecutionContext(), context.GetNodeName(), "[AiCpuNodeExecutorPrepareTask] Start");
--- a/ge/hybrid/node_executor/aicpu/aicpu_node_executor.h
+++ b/ge/hybrid/node_executor/aicpu/aicpu_node_executor.h
@@ -55,12 +55,34 @@ class AicpuNodeTaskBase : public NodeTask {

  virtual Status LaunchTask(TaskContext &context) = 0;

  virtual Status TaskCallback(TaskContext &context) = 0;
  virtual Status InitForDependComputeTask() = 0;

  Status TaskCallback(TaskContext &context);

  virtual Status UpdateShapeAndDataByResultSummary(TaskContext &context);

  virtual Status UpdateIoAddr(TaskContext &context) = 0;

  static Status AllocTensorBuffer(size_t size, std::unique_ptr<TensorBuffer> &tensor_buffer);

  virtual Status CopyDataToHbm(TaskContext &context,
                               const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) = 0;

  ///
  /// read result summary and prepare copy task memory.
  /// @param context task context
  /// @param out_shape_hbm if scalar, TensorBuffer->data is null, size=0
  /// @return SUCCESS:success other:failed
  ///
  Status ReadResultSummaryAndPrepareMemory(TaskContext &context,
                                           std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm);

  Status UpdateShapeByHbmBuffer(TaskContext &context,
                                const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm);

  Status PrepareCopyInputs(const TaskContext &context,
                           const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm);

 protected:
  const NodeItem *node_item_;
  // just reference.
@@ -78,6 +100,14 @@ class AicpuNodeTaskBase : public NodeTask {

  // ext info addr, device mem
  std::unique_ptr<TensorBuffer> ext_info_addr_dev_;

  std::vector<std::unique_ptr<TensorBuffer>> output_summary_;
  std::vector<aicpu::FWKAdapter::ResultSummary> output_summary_host_;

  std::unique_ptr<TensorBuffer> copy_input_release_flag_dev_;
  std::unique_ptr<TensorBuffer> copy_input_data_size_dev_;
  std::unique_ptr<TensorBuffer> copy_input_src_dev_;
  std::unique_ptr<TensorBuffer> copy_input_dst_dev_;
 };

 class AicpuTfNodeTask : public AicpuNodeTaskBase {
@@ -93,33 +123,15 @@ class AicpuTfNodeTask : public AicpuNodeTaskBase {

  Status LaunchTask(TaskContext &context) override;

  Status TaskCallback(TaskContext &context) override;

  Status UpdateIoAddr(TaskContext &context) override;

 private:
  Status SetMemCopyTask(const domi::TaskDef &task_def);

  Status InitForDependComputeTask();

  Status UpdateShapeAndDataByResultSummary(TaskContext &context);

  ///
  /// read result summary and prepare copy task memory.
  /// @param context task context
  /// @param out_shape_hbm if scalar, TensorBuffer->data is null, size=0
  /// @return SUCCESS:success other:failed
  ///
  Status ReadResultSummaryAndPrepareMemory(TaskContext &context,
                                           std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm);
  Status CopyDataToHbm(TaskContext &context,
                       const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm);
                       const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) override;

  Status UpdateShapeByHbmBuffer(TaskContext &context,
                                const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm);
  Status InitForDependComputeTask() override;

  Status PrepareCopyInputs(const TaskContext &context,
                           const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm);
 private:
  Status SetMemCopyTask(const domi::TaskDef &task_def);

  static Status EnsureSessionCreated(uint64_t session_id);
  static uint64_t GetStepIdAddr(const HybridModel &model);
@@ -135,18 +147,11 @@ class AicpuTfNodeTask : public AicpuNodeTaskBase {
  // just used for depend DEPEND_COMPUTE op
  std::unique_ptr<TensorBuffer> copy_task_args_buf_;

  std::vector<std::unique_ptr<TensorBuffer>> output_summary_;
  std::vector<aicpu::FWKAdapter::ResultSummary> output_summary_host_;

  std::unique_ptr<TensorBuffer> copy_ioaddr_dev_;

  std::unique_ptr<TensorBuffer> copy_input_release_flag_dev_;
  std::unique_ptr<TensorBuffer> copy_input_data_size_dev_;
  std::unique_ptr<TensorBuffer> copy_input_src_dev_;
  std::unique_ptr<TensorBuffer> copy_input_dst_dev_;
  bool need_sync_ = false;

  std::unique_ptr<TensorBuffer> copy_workspace_buf_;

  bool need_sync_ = false;
 };

 class AicpuNodeTask : public AicpuNodeTaskBase {
@@ -162,16 +167,30 @@ class AicpuNodeTask : public AicpuNodeTaskBase {

  Status LaunchTask(TaskContext &context) override;

  Status TaskCallback(TaskContext &context) override;
  Status CopyDataToHbm(TaskContext &context,
                       const std::vector<std::unique_ptr<TensorBuffer>> &out_shape_hbm) override;

  Status UpdateIoAddr(TaskContext &context) override;

  Status InitForDependComputeTask() override;
 private:
  Status SetMemCopyTask(const domi::TaskDef &task_def);

 protected:
  // host mem
  std::unique_ptr<uint8_t[]> args_;
    // host memcpy mem
  std::unique_ptr<uint8_t[]> memcpy_args_;

  std::string memcpy_so_name_;

  std::string memcpy_kernel_name_;
  // args size
  uint32_t memcpy_args_size_ = 0;  
  // args size
  uint32_t args_size_ = 0;

  std::vector<uint64_t> copy_io_addr_;
 };

 class AiCpuNodeExecutor : public NodeExecutor {
--- a/ge/single_op/single_op_model.cc
+++ b/ge/single_op/single_op_model.cc
@@ -333,7 +333,7 @@ Status SingleOpModel::BuildTaskList(StreamResource *stream_resource, SingleOp &s
        single_op.tasks_.emplace_back(tbe_task);
      } else if (kernel_type == ccKernelType::AI_CPU || kernel_type == ccKernelType::CUST_AI_CPU) {
        GELOGD("Building AICPU_CC task");
        OpTask *task = nullptr;
        AiCpuCCTask *task = nullptr;
        uint64_t singleop_kernel_id = aicpu_kernel_id++;
        GELOGI("Build singleOp CCTask, kernel_id = %lu", singleop_kernel_id);
        GE_CHK_STATUS_RET_NOLOG(BuildCpuKernelTask(task_def.kernel(), &task, singleop_kernel_id));
@@ -489,7 +489,7 @@ Status SingleOpModel::BuildKernelExTask(const domi::KernelExDef &kernel_def, AiC
  return SUCCESS;
 }

 Status SingleOpModel::BuildCpuKernelTask(const domi::KernelDef &kernel_def, OpTask **task, uint64_t kernel_id) {
 Status SingleOpModel::BuildCpuKernelTask(const domi::KernelDef &kernel_def, AiCpuCCTask **task, uint64_t kernel_id) {
  const auto &context = kernel_def.context();
  auto iter = op_list_.find(context.op_index());
  if (iter == op_list_.end()) {
@@ -611,10 +611,19 @@ Status SingleOpModel::BuildTaskListForDynamicOp(StreamResource *stream_resource,
  } else if (lib_name == kEngineNameAiCpu) {
    const auto &task_def = task_defs[0];
    GELOGD("Building AICPU_CC task");
    OpTask *task = nullptr;
    AiCpuCCTask *task = nullptr;
    uint64_t dynamic_singleop_kernel_id = aicpu_kernel_id++;
    GELOGI("Build dynamic singleOp CCTask, kernel_id = %lu", dynamic_singleop_kernel_id);
    GE_CHK_STATUS_RET_NOLOG(BuildCpuKernelTask(task_def.kernel(), &task, dynamic_singleop_kernel_id));
    if (task->GetUnknownType() == DEPEND_COMPUTE) {
      if (task_defs.size() < kNumTaskWithMemCpyTask) {
        GELOGE(ACL_ERROR_GE_PARAM_INVALID, "[Check][Task]The copy task of the fourth operator was not found.");
        REPORT_INNER_ERROR("E19999", "The copy task of the fourth operator was not found.");
        return ACL_ERROR_GE_PARAM_INVALID;
      }
      const TaskDef &copy_task_def = task_defs[1];
      GE_CHK_STATUS_RET_NOLOG(task->SetMemCopyTask(copy_task_def.kernel()));
    }
    task->SetModelArgs(model_name_, model_id_);
    single_op.op_task_.reset(task);
  } else if (lib_name == kEngineNameAiCpuTf) {
--- a/ge/single_op/single_op_model.h
+++ b/ge/single_op/single_op_model.h
@@ -71,7 +71,7 @@ class SingleOpModel {
  Status BuildKernelTask(const domi::TaskDef &task_def, TbeOpTask **task);
  Status BuildAtomicTask(const domi::TaskDef &task_def, AtomicAddrCleanOpTask **task);
  Status BuildKernelExTask(const domi::KernelExDef &kernel_def, AiCpuTask **task, uint64_t kernel_id);
  Status BuildCpuKernelTask(const domi::KernelDef &kernel_def, OpTask **task, uint64_t kernel_id);
  Status BuildCpuKernelTask(const domi::KernelDef &kernel_def, AiCpuCCTask **task, uint64_t kernel_id);

  static void ParseOpModelParams(ModelHelper &model_helper, SingleOpModelParam &param);
  void ParseArgTable(OpTask *task, SingleOp &op);
--- a/ge/single_op/task/aicpu_kernel_task_builder.cc
+++ b/ge/single_op/task/aicpu_kernel_task_builder.cc
@@ -102,11 +102,8 @@ Status AiCpuCCTaskBuilder::BuildTask(AiCpuCCTask &task, uint64_t kernel_id, cons
    return ret;
  }
  GE_CHK_STATUS_RET(task.SetInputConst(), "[Set][InputConst] failed.");
  GE_CHK_STATUS_RET(task.InitForSummaryAndCopy(), "[Init][SummaryAndCopy] failed.");

  if (task.GetUnknownType() == DEPEND_COMPUTE) {
    GELOGE(FAILED, "[Get][UnknownType] is depend compute, it's not supported now.");
    return FAILED;
  }
  auto aicpu_param_head = reinterpret_cast<aicpu::AicpuParamHead *>(task.args_.get());
  if (task.ext_info_addr_dev_ != nullptr) {
    aicpu_param_head->extInfoLength = kernel_ext_info.size();
--- a/ge/single_op/task/op_task.cc
+++ b/ge/single_op/task/op_task.cc
@@ -583,6 +583,17 @@ AiCpuBaseTask::~AiCpuBaseTask() {
  if (ext_info_addr_dev_ != nullptr) {
    (void)rtFree(ext_info_addr_dev_);
  }

  FreeHbm(copy_input_release_flag_dev_);
  FreeHbm(copy_input_data_size_dev_);
  FreeHbm(copy_input_src_dev_);
  FreeHbm(copy_input_dst_dev_);
  for (auto summary : output_summary_) {
    FreeHbm(summary);
  }
  for (auto out_shape : out_shape_hbm_) {
    FreeHbm(out_shape);
  }
 }

 Status AiCpuBaseTask::SetExtInfoAndType(const std::string &kernel_ext_info, uint64_t kernel_id) {
@@ -593,7 +604,7 @@ Status AiCpuBaseTask::SetExtInfoAndType(const std::string &kernel_ext_info, uint

  int32_t unknown_shape_type_val = 0;
  (void) AttrUtils::GetInt(op_desc_, ::ge::ATTR_NAME_UNKNOWN_SHAPE_TYPE, unknown_shape_type_val);
  GELOGD("Get unknown_type is %d.", unknown_shape_type_val);
  GELOGI("Get unknown_type is %d.", unknown_shape_type_val);
  unknown_type_ = static_cast<UnknowShapeOpType>(unknown_shape_type_val);

  aicpu_ext_handle_.reset(new(std::nothrow) ::ge::hybrid::AicpuExtInfoHandler(op_desc_->GetName(),
@@ -795,17 +806,7 @@ AiCpuTask::~AiCpuTask() {
  FreeHbm(workspace_addr_);
  FreeHbm(copy_workspace_buf_);
  FreeHbm(copy_ioaddr_dev_);
  FreeHbm(copy_input_release_flag_dev_);
  FreeHbm(copy_input_data_size_dev_);
  FreeHbm(copy_input_src_dev_);
  FreeHbm(copy_input_dst_dev_);
  FreeHbm(copy_task_args_buf_);
  for (auto summary : output_summary_) {
    FreeHbm(summary);
  }
  for (auto out_shape : out_shape_hbm_) {
    FreeHbm(out_shape);
  }
 }

 Status AiCpuTask::LaunchKernel(rtStream_t stream) {
@@ -835,7 +836,7 @@ Status AiCpuTask::LaunchKernel(rtStream_t stream) {
  return SUCCESS;
 }

 Status AiCpuTask::PrepareCopyInputs(vector<DataBuffer> &outputs) {
 Status AiCpuBaseTask::PrepareCopyInputs(vector<DataBuffer> &outputs) {
  std::vector<uint64_t> copy_input_release_flag;
  std::vector<uint64_t> copy_input_data_size;
  std::vector<uint64_t> copy_input_src;
@@ -876,7 +877,7 @@ Status AiCpuTask::PrepareCopyInputs(vector<DataBuffer> &outputs) {
  return SUCCESS;
 }

 Status AiCpuTask::ReadResultSummaryAndPrepareMemory() {
 Status AiCpuBaseTask::ReadResultSummaryAndPrepareMemory() {
  for (size_t i = 0; i < num_outputs_; ++i) {
    auto &result_summary = output_summary_host_[i];

@@ -903,7 +904,20 @@ Status AiCpuTask::CopyDataToHbm(vector<DataBuffer> &outputs,
  return SUCCESS;
 }

 Status AiCpuTask::UpdateShapeByHbmBuffer(vector<GeTensorDesc> &output_desc) {
 Status AiCpuCCTask::CopyDataToHbm(vector<DataBuffer> &outputs,
                                  rtStream_t stream) {
  GE_CHK_STATUS_RET_NOLOG(PrepareCopyInputs(outputs));
  
  auto ret = rtCpuKernelLaunchWithFlag(static_cast<const void *>(memcpy_so_name_.data()),
                                       static_cast<const void *>(memcpy_kernel_name_.data()),
                                       block_dim_, memcpy_args_.get(), static_cast<uint32_t>(memcpy_args_size_),
                                       nullptr, stream, RT_KERNEL_DEFAULT);
  GE_CHK_RT_RET(ret);
  GE_CHK_RT_RET(rtStreamSynchronize(stream));
  return SUCCESS;
 }

 Status AiCpuBaseTask::UpdateShapeByHbmBuffer(vector<GeTensorDesc> &output_desc) {
  for (size_t i = 0; i < num_outputs_; ++i) {
    const auto &result_summary = output_summary_host_[i];
    std::vector<int64_t> shape_dims;
@@ -932,7 +946,7 @@ Status AiCpuTask::UpdateShapeByHbmBuffer(vector<GeTensorDesc> &output_desc) {
 }


 Status AiCpuTask::UpdateShapeAndDataByResultSummary(vector<GeTensorDesc> &output_desc,
 Status AiCpuBaseTask::UpdateShapeAndDataByResultSummary(vector<GeTensorDesc> &output_desc,
                                                    vector<DataBuffer> &outputs,
                                                    rtStream_t stream) {
  if (num_outputs_ == 0) {
@@ -1117,16 +1131,112 @@ Status AiCpuCCTask::LaunchKernel(const std::vector<GeTensorDesc> &input_desc,
                                 std::vector<DataBuffer> &output_buffers,
                                 rtStream_t stream) {
  GE_CHK_STATUS_RET_NOLOG(UpdateExtInfo(input_desc, output_desc, stream));
  GE_CHK_STATUS_RET_NOLOG(UpdateIoAddr(input_buffers, output_buffers));
  if (unknown_type_ == DEPEND_COMPUTE) {
    std::vector<DataBuffer> summary_buffers;
    for (size_t i = 0; i < num_outputs_; ++i) {
      summary_buffers.emplace_back(output_summary_[i], sizeof(aicpu::FWKAdapter::ResultSummary), false);
    }
    GE_CHK_STATUS_RET_NOLOG(UpdateIoAddr(input_buffers, summary_buffers));
  } else {
    GE_CHK_STATUS_RET_NOLOG(UpdateIoAddr(input_buffers, output_buffers));
  }
  GE_CHK_STATUS_RET_NOLOG(LaunchKernel(stream));
  if (unknown_type_ == DEPEND_SHAPE_RANGE) {
    GE_CHK_RT_RET(rtStreamSynchronize(stream));
    GE_CHK_STATUS_RET_NOLOG(UpdateOutputShape(output_desc));
  } else if (unknown_type_ == DEPEND_COMPUTE) {
    GE_CHK_RT_RET(rtStreamSynchronize(stream));
    GE_CHK_STATUS_RET_NOLOG(UpdateShapeAndDataByResultSummary(output_desc, output_buffers, stream));
  }

  return SUCCESS;
 }

 Status AiCpuCCTask::InitForSummaryAndCopy() {
  if (unknown_type_ != DEPEND_COMPUTE || num_outputs_ == 0) {
    GELOGI("Unknown_type is %d, output num is %zu.", unknown_type_, num_outputs_);
    return SUCCESS;
  }

  output_summary_.resize(num_outputs_);
  constexpr auto result_summary_size = sizeof(aicpu::FWKAdapter::ResultSummary);
  for (size_t i = 0; i < num_outputs_; ++i) {
    GE_CHK_RT_RET(rtMalloc(&output_summary_[i], result_summary_size, RT_MEMORY_HBM));
  }
  output_summary_host_.resize(num_outputs_);

  const size_t copy_input_buf_len = num_outputs_ * kCopyNum * sizeof(uint64_t);

  GE_CHK_RT_RET(rtMalloc(&copy_input_release_flag_dev_, copy_input_buf_len, RT_MEMORY_HBM));
  GE_CHK_RT_RET(rtMalloc(&copy_input_data_size_dev_, copy_input_buf_len, RT_MEMORY_HBM));
  GE_CHK_RT_RET(rtMalloc(&copy_input_src_dev_, copy_input_buf_len, RT_MEMORY_HBM));
  GE_CHK_RT_RET(rtMalloc(&copy_input_dst_dev_, copy_input_buf_len, RT_MEMORY_HBM));

  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_release_flag_dev_));
  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_data_size_dev_));
  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_src_dev_));
  copy_io_addr_.emplace_back(reinterpret_cast<uintptr_t>(copy_input_dst_dev_));
  return SUCCESS;
 }

 Status AiCpuCCTask::SetMemCopyTask(const domi::KernelDef &kernel_def) {
  auto &memcpy_args = kernel_def.args();
  memcpy_args_size_ = kernel_def.args_size();
  memcpy_so_name_ = kernel_def.so_name();
  memcpy_kernel_name_ = kernel_def.kernel_name();
  if (memcpy_args.size() != memcpy_args_size_) {
    REPORT_INNER_ERROR("E19999", "MemCopy task def args.size=%zu, but args_size=%u not equal.",
                       memcpy_args.size(), memcpy_args_size_);
    GELOGE(FAILED, "[Check][Size]MemCopy task def args.size=%zu, but args_size=%u not equal.",
           memcpy_args.size(), memcpy_args_size_);
    return FAILED;
  }
  if (memcpy_args_size_ < sizeof(aicpu::AicpuParamHead)) {
    REPORT_INNER_ERROR("E19999",
                       "Task def args_size=%u is less than aicpu param head len=%zu.",
                       memcpy_args_size_, sizeof(aicpu::AicpuParamHead));
    GELOGE(FAILED,
           "[Check][Size] Task def args_size=%u is less than aicpu param head len=%zu.",
           memcpy_args_size_, sizeof(aicpu::AicpuParamHead));
    return FAILED;
  }

  memcpy_args_.reset(new(std::nothrow) uint8_t[memcpy_args_size_]());
  if (memcpy_args_ == nullptr) {
    REPORT_INNER_ERROR("E19999", "new memory failed for Node[MemCopy], task_size[%u].",
                       memcpy_args_size_);
    GELOGE(FAILED, "[Malloc][Memory] failed for Node[MemCopy], task_size[%u].",
           memcpy_args_size_);
    return FAILED;
  }

  errno_t sec_ret = memcpy_s(memcpy_args_.get(), memcpy_args_size_, memcpy_args.c_str(), memcpy_args.size());
  if (sec_ret != EOK) {
    REPORT_INNER_ERROR("E19999",
                       "memcpy_s argc_ failed for Node[MemCopy], ret: %d", sec_ret);
    GELOGE(INTERNAL_ERROR,
           "[Update][args] failed for Node[MemCopy], ret: %d", sec_ret);
    return sec_ret;
  }
  auto memcpy_param_head = reinterpret_cast<aicpu::AicpuParamHead *>(memcpy_args_.get());
  uint32_t memcpy_io_num = memcpy_param_head->ioAddrNum;
  auto memcpy_io_addr = memcpy_args_.get() + sizeof(aicpu::AicpuParamHead);
  // if has input and output, need copy to ioaddr
  int cpy_ret = memcpy_s(memcpy_io_addr, memcpy_args_size_ - sizeof(aicpu::AicpuParamHead),
                         &copy_io_addr_[0], sizeof(uint64_t) * memcpy_io_num);
  if (cpy_ret != 0) {
    REPORT_INNER_ERROR("E19999", "Node[Memcpoy] memcpy io addr to AicpuParamHead failed,"
            "ret=%d, args_size=%u, io nums=%u.",
            cpy_ret, memcpy_args_size_, memcpy_io_num);
    GELOGE(INTERNAL_ERROR, "[Update][io_addr]Node[MemCopy] memcpy io addr to AicpuParamHead failed,"
            "ret=%d, args_size=%u, io nums=%u.",
            cpy_ret, memcpy_args_size_, memcpy_io_num);
    return INTERNAL_ERROR;
  }
  GELOGD("Set memcpy task for node[MemCopy] successfully.");
  return SUCCESS;
 }

 void AiCpuCCTask::GetIoAddr(uintptr_t *&arg_base, size_t &arg_count) {
  arg_base = io_addr_;
  arg_count = io_addr_num_;
--- a/ge/single_op/task/op_task.h
+++ b/ge/single_op/task/op_task.h
@@ -179,7 +179,17 @@ class AiCpuBaseTask : public OpTask {
                       rtStream_t stream);
  Status UpdateOutputShape(vector<GeTensorDesc> &output_desc);
  Status UpdateShapeToOutputDesc(const GeShape &shape_new, GeTensorDesc &output_desc);
  
  Status UpdateShapeAndDataByResultSummary(vector<GeTensorDesc> &output_desc,
                                           vector<DataBuffer> &outputs,
                                           rtStream_t stream);
  Status ReadResultSummaryAndPrepareMemory();

  Status PrepareCopyInputs(vector<DataBuffer> &outputs);

  Status UpdateShapeByHbmBuffer(vector<GeTensorDesc> &output_desc);

  virtual Status CopyDataToHbm(vector<DataBuffer> &outputs, rtStream_t stream) = 0;
 protected:
  size_t num_inputs_ = 0;
  size_t num_outputs_ = 0;
@@ -187,6 +197,16 @@ class AiCpuBaseTask : public OpTask {
  std::unique_ptr<ge::hybrid::AicpuExtInfoHandler> aicpu_ext_handle_;
  void *ext_info_addr_dev_ = nullptr;
  vector<bool> input_is_const_;
  
  std::vector<void *> output_summary_;
  std::vector<aicpu::FWKAdapter::ResultSummary> output_summary_host_;

  void *copy_input_release_flag_dev_ = nullptr;
  void *copy_input_data_size_dev_ = nullptr;
  void *copy_input_src_dev_ = nullptr;
  void *copy_input_dst_dev_ = nullptr;

  vector<void *> out_shape_hbm_;
 };

 class AiCpuTask : public AiCpuBaseTask {
@@ -207,16 +227,9 @@ class AiCpuTask : public AiCpuBaseTask {
 private:
  // for copy task.
  Status InitForSummaryAndCopy();
  Status UpdateShapeAndDataByResultSummary(vector<GeTensorDesc> &output_desc,
                                           vector<DataBuffer> &outputs,
                                           rtStream_t stream);
  Status ReadResultSummaryAndPrepareMemory();

  Status CopyDataToHbm(vector<DataBuffer> &outputs, rtStream_t stream);
  Status PrepareCopyInputs(vector<DataBuffer> &outputs);

  Status UpdateShapeByHbmBuffer(vector<GeTensorDesc> &output_desc);

  Status CopyDataToHbm(vector<DataBuffer> &outputs, rtStream_t stream) override;
 private:
  friend class AiCpuTaskBuilder;
  void *workspace_addr_ = nullptr;
  std::string task_info_;
@@ -235,17 +248,7 @@ class AiCpuTask : public AiCpuBaseTask {
  void *copy_task_args_buf_ = nullptr;
  void *copy_workspace_buf_ = nullptr;

  std::vector<void *> output_summary_;
  std::vector<aicpu::FWKAdapter::ResultSummary> output_summary_host_;

  void *copy_ioaddr_dev_ = nullptr;

  void *copy_input_release_flag_dev_ = nullptr;
  void *copy_input_data_size_dev_ = nullptr;
  void *copy_input_src_dev_ = nullptr;
  void *copy_input_dst_dev_ = nullptr;

  vector<void *> out_shape_hbm_;
  uint64_t kernel_id_ = 0;
 };

@@ -264,13 +267,16 @@ class AiCpuCCTask : public AiCpuBaseTask {
  void SetkernelName(const std::string &kernel_Name);
  void SetIoAddr(uintptr_t *io_addr);
  size_t GetArgSize() const;

  Status SetMemCopyTask(const domi::KernelDef &kernel_def);
  Status LaunchKernel(const std::vector<GeTensorDesc> &input_desc,
                      const std::vector<DataBuffer> &input_buffers,
                      std::vector<GeTensorDesc> &output_desc,
                      std::vector<DataBuffer> &output_buffers,
                      rtStream_t stream)  override;
 private:
  Status InitForSummaryAndCopy();

  Status CopyDataToHbm(vector<DataBuffer> &outputs, rtStream_t stream) override;
 private:
  friend class AiCpuCCTaskBuilder;
  std::string so_name_;
@@ -284,6 +290,13 @@ private:
  uint32_t dump_flag_ = RT_KERNEL_DEFAULT;
  std::string op_type_;
  uint64_t kernel_id_ = 0;
  // host memcpy mem
  std::unique_ptr<uint8_t[]> memcpy_args_;
  std::string memcpy_so_name_;
  std::string memcpy_kernel_name_;
  std::vector<uint64_t> copy_io_addr_;
  // args size
  uint32_t memcpy_args_size_ = 0;
 };

 class MemcpyAsyncTask : public OpTask {
--- a/tests/ut/ge/hybrid/node_executor/aicpu/aicpu_node_executor_unittest.cc
+++ b/tests/ut/ge/hybrid/node_executor/aicpu/aicpu_node_executor_unittest.cc
@@ -148,21 +148,30 @@ TEST_F(UtestAicpuNodeExecutor, aicpu_tf_node_task) {

  domi::TaskDef task_def2;
  task_def2.set_type(RT_MODEL_TASK_ALL_KERNEL);
  task_def2.mutable_kernel()->set_args(reinterpret_cast<const char *>(&args), args.head.length);
  task_def2.mutable_kernel()->set_args_size(args.head.length);

  hybrid_model.task_defs_[node] = std::vector<domi::TaskDef>({task_def2});

  AicpuNodeTask aicpu_node_task(node_item, task_def);
  ASSERT_EQ(aicpu_node_task.Init(hybrid_model), FAILED);
  domi::KernelDef *kernel_def = task_def2.mutable_kernel();
  kernel_def->set_args(reinterpret_cast<const char *>(&args), args.head.length);
  kernel_def->set_args_size(args.head.length);
  AicpuExtInfo aicpu_ext_info2;
  aicpu_ext_info2.infoType = aicpu::FWKAdapter::FWK_ADPT_EXT_SHAPE_TYPE;
  aicpu_ext_info2.infoLen = sizeof(int32_t);
  memcpy_s(aicpu_ext_info2.infoMsg, sizeof(int32_t), &type, sizeof(int32_t));
  char *ext_mem2 = (char*)malloc(sizeof(AicpuExtInfo) + sizeof(int32_t));
  memcpy_s(ext_mem2, sizeof(AicpuExtInfo) + sizeof(int32_t), &aicpu_ext_info2, sizeof(AicpuExtInfo) + sizeof(int32_t));
  kernel_def->set_kernel_ext_info(ext_mem2, sizeof(AicpuExtInfo) + sizeof(int32_t));
  kernel_def->set_kernel_ext_info_size(sizeof(AicpuExtInfo) + sizeof(int32_t));
  hybrid_model.task_defs_[node] = std::vector<domi::TaskDef>({task_def2, task_def2});

  AicpuNodeTask aicpu_node_task(node_item, task_def2);
  ASSERT_EQ(aicpu_node_task.Init(hybrid_model), SUCCESS);
  ASSERT_EQ(aicpu_node_task.UpdateIoAddr(*node_state->GetTaskContext()), SUCCESS);
  ASSERT_EQ(aicpu_node_task.LaunchTask(*node_state->GetTaskContext()), SUCCESS);


  
  node_item->is_dynamic = false;
  ASSERT_EQ(aicpu_node_task.UpdateIoAddr(*node_state->GetTaskContext()), SUCCESS);
  //kernel_ex_def->set_allocated_kernel_ext_info(nullptr);

  free(ext_mem);

  free(ext_mem2);
 }

 }  // namespace ge

--- a/tests/ut/ge/single_op/single_op_model_unittest.cc
+++ b/tests/ut/ge/single_op/single_op_model_unittest.cc
@@ -25,6 +25,7 @@
 #include "single_op/single_op_model.h"
 #include "single_op/task/tbe_task_builder.h"
 #include "single_op/task/rts_kernel_task_builder.h"
 #include "aicpu/common/aicpu_task_struct.h"
 #include "single_op/task/op_task.h"
 #include "framework/common/helper/model_helper.h"
 #include "single_op/single_op.h"
@@ -43,6 +44,11 @@ constexpr char const *kAttrSupportDynamicShape = "support_dynamicshape";
 const char *const kEngineNameAiCore = "AIcoreEngine";
 const char *const kEngineNameAiCpu = "aicpu_ascend_kernel";
 const char *const kEngineNameAiCpuTf = "aicpu_tf_kernel";

 struct AicpuTaskStruct {
  aicpu::AicpuParamHead head;
  uint64_t io_addrp[6];
 }__attribute__((packed));
 }  // namespace

 class UtestSingleOpModel : public testing::Test {
@@ -315,7 +321,7 @@ TEST_F(UtestSingleOpModel, BuildTaskList) {
  ASSERT_EQ(mem_task.LaunchKernel(0), SUCCESS);
 }

 TEST_F(UtestSingleOpModel, build_dynamic_task) {
 TEST_F(UtestSingleOpModel, build_dynamic_task01) {
  ComputeGraphPtr graph = make_shared<ComputeGraph>("single_op");
  GeModelPtr ge_model = make_shared<GeModel>();
  ge_model->SetGraph(GraphUtils::CreateGraphFromComputeGraph(graph));
@@ -366,3 +372,50 @@ TEST_F(UtestSingleOpModel, build_dynamic_task) {
  op_desc->SetOpKernelLibName(kEngineNameAiCpu);
  model.BuildTaskListForDynamicOp(res, single_op);
 }

 TEST_F(UtestSingleOpModel, build_dynamic_task02) {
  ComputeGraphPtr graph = make_shared<ComputeGraph>("single_op");
  GeModelPtr ge_model = make_shared<GeModel>();
  ge_model->SetGraph(GraphUtils::CreateGraphFromComputeGraph(graph));
  shared_ptr<domi::ModelTaskDef> model_task_def = make_shared<domi::ModelTaskDef>();
  ge_model->SetModelTaskDef(model_task_def);
  
  AicpuTaskStruct args;
  args.head.length = sizeof(args);
  args.head.ioAddrNum = 6;
  domi::TaskDef *task_def = model_task_def->add_task();
  task_def->set_type(RT_MODEL_TASK_KERNEL);
  domi::KernelDef *kernel_def = task_def->mutable_kernel();
  kernel_def->set_args(reinterpret_cast<const char *>(&args), args.head.length);
  kernel_def->set_args_size(args.head.length);
  ge::hybrid::AicpuExtInfo aicpu_ext_info;
  aicpu_ext_info.infoType = aicpu::FWKAdapter::FWK_ADPT_EXT_SHAPE_TYPE;
  aicpu_ext_info.infoLen = sizeof(int32_t);
  int32_t type = ge::DEPEND_COMPUTE;
  memcpy_s(aicpu_ext_info.infoMsg, sizeof(int32_t), &type, sizeof(int32_t));
  char *ext_mem = (char*)malloc(sizeof(ge::hybrid::AicpuExtInfo) + sizeof(int32_t));
  memcpy_s(ext_mem, sizeof(ge::hybrid::AicpuExtInfo) + sizeof(int32_t), &aicpu_ext_info,
           sizeof(ge::hybrid::AicpuExtInfo) + sizeof(int32_t));
  kernel_def->set_kernel_ext_info(ext_mem, sizeof(ge::hybrid::AicpuExtInfo) + sizeof(int32_t));
  kernel_def->set_kernel_ext_info_size(sizeof(ge::hybrid::AicpuExtInfo) + sizeof(int32_t));
  domi::KernelContext *context = kernel_def->mutable_context();
  context->set_kernel_type(6);    // ccKernelType::AI_CPU

  string model_data_str = "dynamic_model";
  SingleOpModel model("model", model_data_str.c_str(), model_data_str.size());
  std::mutex stream_mu;
  rtStream_t stream = nullptr;
  rtStreamCreate(&stream, 0);
  DynamicSingleOp single_op(0, &stream_mu, stream);
  model.model_helper_.model_ = ge_model;
  auto op_desc = std::make_shared<ge::OpDesc>("add", "Add");
  AttrUtils::SetInt(op_desc, ::ge::ATTR_NAME_UNKNOWN_SHAPE_TYPE, ge::DEPEND_COMPUTE);
  NodePtr node = graph->AddNode(op_desc); 
  model.op_list_[0] = node;
  StreamResource *res = new (std::nothrow) StreamResource(1);

  ASSERT_EQ(model.ParseTasks(), SUCCESS);
  model.node_tasks_[node] = { *task_def, *task_def };
  op_desc->SetOpKernelLibName(kEngineNameAiCpu);
  model.BuildTaskListForDynamicOp(res, single_op);
 }
--- a/tests/ut/ge/single_op/single_op_task_unittest.cc
+++ b/tests/ut/ge/single_op/single_op_task_unittest.cc
@@ -238,6 +238,28 @@ TEST_F(UtestSingleOpTask, test_aicpu_task_update_io_addr) {
  }
 }

 TEST_F(UtestSingleOpTask, test_aicpu_task_launch_kernel) {
  AiCpuCCTask task;
  rtStream_t stream = nullptr;
  task.num_inputs_ = 2;
  task.num_outputs_ = 1;
  task.input_is_const_ = {true, false};
  int total_addr = 3;
  uint32_t* addrs[total_addr] = {nullptr, nullptr, nullptr};
  task.io_addr_ = reinterpret_cast<uintptr_t*>(addrs);
  task.io_addr_num_ = total_addr;

  {
    vector<DataBuffer> inputs(2, DataBuffer());
    vector<DataBuffer> outputs(1, DataBuffer());
    vector<GeTensorDesc> inputs_desc(2, GeTensorDesc(GeShape(), FORMAT_NCHW, DT_FLOAT));
    vector<GeTensorDesc> outputs_desc(1, GeTensorDesc(GeShape(), FORMAT_NCHW, DT_FLOAT));
    task.unknown_type_ = ge::DEPEND_COMPUTE;
    task.num_outputs_ = 1;
    ASSERT_EQ(task.InitForSummaryAndCopy(), SUCCESS);
    ASSERT_EQ(task.LaunchKernel(inputs_desc, inputs, outputs_desc, outputs, stream), SUCCESS);
  }

 TEST_F(UtestSingleOpTask, test_dynamic_support) {
  auto graph = make_shared<ComputeGraph>("graph");
  auto op_desc = make_shared<OpDesc>("Add", "Add");