!1234 update ge_0311

From: @shenwei41 Reviewed-by: @xsmq Signed-off-by:
4 years ago · 8737b1843d
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@@ -76,21 +76,17 @@ if (ENABLE_OPEN_SRC)
        find_module(runtime libruntime.so ${GE_LIB_PATH})
        find_module(runtime_compile libruntime_compile.so ${GE_LIB_PATH})
        find_module(resource libresource.so ${GE_LIB_PATH})
        find_module(error_manager liberror_manager.so ${GE_LIB_PATH})
        find_module(ascend_hal_stub libascend_hal.so ${GE_LIB_PATH})
        find_module(error_manager_static liberror_manager.a ${GE_LIB_PATH})
        find_module(msprofiler_fwk_ext libmsprofiler_fwk.a ${GE_LIB_PATH})
        #find_module(ascendcl_static libascendcl.a ${GE_LIB_PATH})
    elseif(ENABLE_GE_COV OR ENABLE_GE_UT)
 	add_subdirectory(tests)
    else()
        find_module(slog libslog.so ${ASCEND_ATC_DIR} ${ASCEND_DRIVER_COMMON_DIR})
        find_module(slog libalog.so ${ASCEND_ATC_DIR} ${ASCEND_DRIVER_COMMON_DIR})
        find_module(static_mmpa libmmpa.a ${ASCEND_ATC_DIR} ${ASCEND_RUNTIME_DIR})
        find_module(error_manager liberror_manager.so ${ASCEND_ATC_DIR} ${ASCEND_RUNTIME_DIR})
        if(PLATFORM STREQUAL "train")
            find_module(adump_server libadump_server.a ${ASCEND_RUNTIME_DIR})
            find_module(runtime libruntime.so ${ASCEND_RUNTIME_DIR})
            find_module(error_manager liberror_manager.so ${ASCEND_RUNTIME_DIR})
            find_module(msprofiler_fwk_ext libmsprofiler_fwk.a ${ASCEND_RUNTIME_DIR})
            find_module(ascend_hal_stub libascend_hal.so ${ASCEND_DRIVER_DIR}/driver)
            if(PRODUCT STREQUAL "flr3")
@@ -100,8 +96,6 @@ if (ENABLE_OPEN_SRC)
            find_module(adump_server libadump_server.a ${ASCEND_ACL_DIR})
            find_module(runtime libruntime.so ${ASCEND_ACL_DIR})
 	    find_module(runtime_compile libruntime_compile.so ${ASCEND_ATC_DIR})
            find_module(error_manager liberror_manager.so ${ASCEND_ATC_DIR})
            find_module(error_manager_static liberror_manager.a ${ASCEND_ACL_DIR})
            find_module(msprofiler_ext libmsprofiler.a ${ASCEND_ACL_DIR})
            if(PRODUCT STREQUAL "flr3")
            elseif(PRODUCT STREQUAL "flr1")
@@ -114,11 +108,9 @@ if (ENABLE_OPEN_SRC)
        elseif(PLATFORM STREQUAL "all")
 	    find_module(adump_server libadump_server.a ${ASCEND_RUNTIME_DIR})
 	    find_module(runtime libruntime.so ${ASCEND_RUNTIME_DIR})
 	    find_module(error_manager liberror_manager.so ${ASCEND_RUNTIME_DIR})
            find_module(msprofiler_fwk_ext libmsprofiler_fwk.a ${ASCEND_RUNTIME_DIR})
 	    find_module(ascend_hal_stub libascend_hal.so ${ASCEND_DRIVER_DIR})
 	    find_module(runtime_compile libruntime_compile.so ${ASCEND_ATC_DIR})
 	    find_module(error_manager_static liberror_manager.a ${ASCEND_ACL_DIR})
 	    find_module(msprofiler_ext libmsprofiler.a ${ASCEND_ACL_DIR})
        else()
            message(STATUS "PLATFORM param is invalid, should be train or inference, you choose nothing!")
@@ -144,7 +136,6 @@ elseif (ENABLE_D OR ENABLE_ACL)
    # common libraries
    find_module(slog libalog.so ${ASCEND_MS_RUNTIME_PATH} ${ATLAS_MS_RUNTIME_PATH})
    find_module(error_manager liberror_manager.so ${ASCEND_MS_RUNTIME_PATH} ${ATLAS_MS_RUNTIME_PATH})
    find_module(static_mmpa libmmpa.a ${ASCEND_MS_RUNTIME_PATH} ${ATLAS_MS_RUNTIME_PATH})
    if (ENABLE_D)
@@ -164,7 +155,6 @@ elseif(ENABLE_MS_TESTCASES)
    # common libraries
    find_module(slog libalog.so ${ASCEND_MS_RUNTIME_PATH} ${ATLAS_MS_RUNTIME_PATH})
    find_module(error_manager liberror_manager.so ${ASCEND_MS_RUNTIME_PATH} ${ATLAS_MS_RUNTIME_PATH})
    find_module(static_mmpa libmmpa.a ${ASCEND_MS_RUNTIME_PATH} ${ATLAS_MS_RUNTIME_PATH})
    set(METADEF_DIR ${CMAKE_CURRENT_LIST_DIR}/metadef)
--- a/build.sh
+++ b/build.sh
@@ -76,8 +76,8 @@ checkopts()
        ENABLE_GE_ST="on"
        ;;
      t)
 	      ENABLE_GE_UT="on"
 	      ;;
        ENABLE_GE_UT="on"
        ;;
      c)
        ENABLE_GE_COV="on"
        ;;
@@ -185,7 +185,7 @@ build_graphengine()
    # build all the target
    TARGET="ge_runner ge_compiler fwk_atc.bin atc_atc.bin opensrc_ascendcl ${TARGET}"
  fi
  make ${VERBOSE} ${TARGET} -j${THREAD_NUM} && make install
  if [ $? -ne 0 ]
  then
@@ -214,13 +214,14 @@ if [[ "X$ENABLE_GE_UT" = "Xon" || "X$ENABLE_GE_COV" = "Xon" ]]; then
    cp ${BUILD_PATH}/tests/ut/ge/ut_libge_others_utest ${OUTPUT_PATH}
    cp ${BUILD_PATH}/tests/ut/ge/ut_libge_kernel_utest ${OUTPUT_PATH}
    ${OUTPUT_PATH}/ut_libgraph &&
    ${OUTPUT_PATH}/ut_libge_multiparts_utest &&
    ${OUTPUT_PATH}/ut_libge_distinct_load_utest &&
    ${OUTPUT_PATH}/ut_libge_others_utest &&
    ${OUTPUT_PATH}/ut_libge_kernel_utest
    RUN_TEST_CASE=${OUTPUT_PATH}/ut_libgraph && ${RUN_TEST_CASE} &&
    RUN_TEST_CASE=${OUTPUT_PATH}/ut_libge_multiparts_utest && ${RUN_TEST_CASE} &&
    RUN_TEST_CASE=${OUTPUT_PATH}/ut_libge_distinct_load_utest && ${RUN_TEST_CASE} &&
    RUN_TEST_CASE=${OUTPUT_PATH}/ut_libge_others_utest && ${RUN_TEST_CASE} &&
    RUN_TEST_CASE=${OUTPUT_PATH}/ut_libge_kernel_utest && ${RUN_TEST_CASE}
    if [[ "$?" -ne 0 ]]; then
        echo "!!! UT FAILED, PLEASE CHECK YOUR CHANGES !!!"
        echo -e "\033[31m${RUN_TEST_CASE}\033[0m"
        exit 1;
    fi
    echo "Generating coverage statistics, please wait..."
@@ -249,8 +250,8 @@ generate_package()
  NNENGINE_PATH="plugin/nnengine/ge_config"
  OPSKERNEL_PATH="plugin/opskernel"
  ATC_LIB=("libc_sec.so" "libge_common.so" "libge_compiler.so" "libgraph.so" "libregister.so")
  FWK_LIB=("libge_common.so" "libge_runner.so" "libgraph.so" "libregister.so")
  ATC_LIB=("libc_sec.so" "libge_common.so" "libge_compiler.so" "libgraph.so" "libregister.so" "liberror_manager.so")
  FWK_LIB=("libge_common.so" "libge_runner.so" "libgraph.so" "libregister.so" "liberror_manager.so")
  PLUGIN_OPSKERNEL=("libge_local_engine.so" "libge_local_opskernel_builder.so" "libhost_cpu_engine.so" "libhost_cpu_opskernel_builder.so" "optimizer_priority.pbtxt")
  PARSER_LIB=("lib_caffe_parser.so" "libfmk_onnx_parser.so" "libfmk_parser.so" "libparser_common.so")
@@ -269,7 +270,7 @@ generate_package()
  mk_dir "${OUTPUT_PATH}/${FWK_BIN_PATH}"
  mk_dir "${OUTPUT_PATH}/${FWK_INCLUDE_PATH}"
  mk_dir "${OUTPUT_PATH}/${ATC_INCLUDE_PATH}"
  cd "${OUTPUT_PATH}"
  find ./ -name graphengine_lib.tar -exec rm {} \;
--- a/cmake/external_libs/gtest.cmake
+++ b/cmake/external_libs/gtest.cmake
@@ -27,7 +27,7 @@ ExternalProject_Add(gtest_build
                    URL ${REQ_URL}
                    TLS_VERIFY OFF
                    CONFIGURE_COMMAND ${CMAKE_COMMAND} -DCMAKE_CXX_FLAGS=${gtest_CXXFLAGS} -DCMAKE_INSTALL_PREFIX=${CMAKE_INSTALL_PREFIX}/gtest <SOURCE_DIR>
                -DBUILD_TESTING=OFF -DCMAKE_POSITION_INDEPENDENT_CODE=ON -DBUILD_SHARED_LIBS=ON -DCMAKE_MACOSX_RPATH=TRUE -Dgtest_disable_pthreads=ON
                    -DBUILD_TESTING=OFF -DCMAKE_POSITION_INDEPENDENT_CODE=ON -DBUILD_SHARED_LIBS=ON -DCMAKE_MACOSX_RPATH=TRUE
                    BUILD_COMMAND $(MAKE)
                    INSTALL_COMMAND $(MAKE) install
                    EXCLUDE_FROM_ALL TRUE 
@@ -52,10 +52,27 @@ set_target_properties(gtest_main PROPERTIES
 target_include_directories(gtest INTERFACE ${GTEST_PKG_DIR}/include)
 target_include_directories(gtest_main INTERFACE ${GTEST_PKG_DIR}/include)
 add_library(gmock SHARED IMPORTED)
 set_target_properties(gmock PROPERTIES
    IMPORTED_LOCATION ${GTEST_PKG_DIR}/lib/libgmock.so
 )
 add_library(gmock_main SHARED IMPORTED)
 set_target_properties(gmock_main PROPERTIES
    IMPORTED_LOCATION ${GTEST_PKG_DIR}/lib/libgmock_main.so
 )
 target_include_directories(gmock INTERFACE ${GTEST_PKG_DIR}/include)
 target_include_directories(gmock_main INTERFACE ${GTEST_PKG_DIR}/include)
 set(INSTALL_BASE_DIR "")
 set(INSTALL_LIBRARY_DIR lib)
 install(FILES ${GTEST_PKG_DIR}/lib/libgtest.so ${GTEST_PKG_DIR}/lib/libgtest_main.so OPTIONAL
 install(FILES ${GTEST_PKG_DIR}/lib/libgtest.so ${GTEST_PKG_DIR}/lib/libgtest_main.so ${GTEST_PKG_DIR}/lib/libgmock.so ${GTEST_PKG_DIR}/lib/libgmock_main.so OPTIONAL
        DESTINATION ${INSTALL_LIBRARY_DIR})
 add_dependencies(gtest gtest_build)
--- a/ge/CMakeLists.txt
+++ b/ge/CMakeLists.txt
@@ -103,6 +103,7 @@ set(TRAIN_SRC_LIST
    "common/profiling/profiling_manager.cc"
    "common/dump/dump_manager.cc"
    "common/dump/dump_properties.cc"
    "common/dump/opdebug_register.cc"
    "common/dump/dump_op.cc"
    "common/profiling/ge_profiling.cc"
    "common/profiling/ge_runner_profiling.cc"
@@ -133,7 +134,6 @@ set(TRAIN_SRC_LIST
    "graph/load/model_manager/data_dumper.cc"
    "graph/load/model_manager/data_inputer.cc"
    "graph/load/model_manager/davinci_model.cc"
    "graph/load/model_manager/davinci_model_parser.cc"
    "graph/load/model_manager/model_manager.cc"
    "graph/load/model_manager/model_utils.cc"
    "graph/load/model_manager/aipp_utils.cc"
@@ -428,6 +428,7 @@ set(INFER_SRC_LIST
    "common/dump/dump_properties.cc"
    "common/dump/dump_manager.cc"
    "common/dump/dump_op.cc"
    "common/dump/opdebug_register.cc"
    "common/dump/dump_server.cc"
    "common/helper/model_cache_helper.cc"
    "ge_local_engine/engine/host_cpu_engine.cc"
@@ -613,7 +614,6 @@ set(INFER_SRC_LIST
    "graph/load/model_manager/model_manager.cc"
    "graph/load/model_manager/data_inputer.cc"
    "graph/load/model_manager/davinci_model.cc"
    "graph/load/model_manager/davinci_model_parser.cc"
    "graph/load/model_manager/model_utils.cc"
    "graph/load/model_manager/aipp_utils.cc"
    "graph/load/model_manager/tbe_handle_store.cc"
--- a/ge/analyzer/analyzer.cc
+++ b/ge/analyzer/analyzer.cc
@@ -103,7 +103,7 @@ ge::Status Analyzer::Initialize() {
  // Initialize file
  string real_path = RealPath(kFilePath.c_str());
  if (real_path.empty()) {
    GELOGE(FAILED, "File path is invalid.");
    GELOGE(FAILED, "[Check][AnalyzeFilePath]File path is empty, Path invalid.");
    return FAILED;
  }
  json_file_name_ = real_path + "/" + kAnalyzeFile;
@@ -155,12 +155,12 @@ std::shared_ptr<GraphInfo> Analyzer::GetJsonObject(uint64_t session_id, uint64_t
  std::lock_guard<std::recursive_mutex> lg(mutex_);
  auto iter = graph_infos_.find(session_id);
  if (iter == graph_infos_.end()) {
    GELOGE(PARAM_INVALID, "session_id:%lu does not exist!", session_id);
    GELOGE(PARAM_INVALID, "[Check][Session_id]session_id:%lu does not exist! graph_id:%lu.", session_id, graph_id);
    return nullptr;
  } else {
    auto iter1 = (iter->second).find(graph_id);
    if (iter1 == (iter->second).end()) {
      GELOGE(PARAM_INVALID, "graph_id:%lu does not exist!", graph_id);
      GELOGE(PARAM_INVALID, "[Check][Graph_id]graph_id:%lu does not exist! session_id:%lu.", graph_id, session_id);
      return nullptr;
    }
    GELOGI("GetJsonObject Success!session_id:%lu graph_id:%lu", session_id, graph_id);
@@ -186,11 +186,11 @@ ge::Status Analyzer::CreateAnalyzerFile() {
  std::lock_guard<std::mutex> lg(file_mutex_);
  int fd = open(json_file_name_.c_str(), O_WRONLY | O_CREAT | O_TRUNC, kFileAuthority);
  if (fd < 0) {
    GELOGE(INTERNAL_ERROR, "Fail to open the file: %s.", json_file_name_.c_str());
    GELOGE(INTERNAL_ERROR, "[FileOpen][AnalyzeFile]Fail to open the analyze file: %s.", json_file_name_.c_str());
    return INTERNAL_ERROR;
  }
  if (close(fd) != 0) {
    GELOGE(INTERNAL_ERROR, "Fail to close the file: %s.", json_file_name_.c_str());
    GELOGE(INTERNAL_ERROR, "[FileClose][AnalyzeFile]Fail to close the analyze file: %s.", json_file_name_.c_str());
    return INTERNAL_ERROR;
  }
  is_json_file_create_ = true;
@@ -200,7 +200,7 @@ ge::Status Analyzer::CreateAnalyzerFile() {
 }
 ge::Status Analyzer::SaveAnalyzerDataToFile(uint64_t session_id, uint64_t graph_id) {
  GELOGD("start to save analyze file!");
  GELOGD("start to save analyze file.");
  auto graph_info = GetJsonObject(session_id, graph_id);
  GE_CHECK_NOTNULL(graph_info);
@@ -211,7 +211,7 @@ ge::Status Analyzer::SaveAnalyzerDataToFile(uint64_t session_id, uint64_t graph_
  std::lock_guard<std::mutex> lg(file_mutex_);
  json_file_.open(json_file_name_, std::ios::app);
  if (!json_file_.is_open()) {
    GELOGE(FAILED, "analyzer file does not exist[%s]", json_file_name_.c_str());
    GELOGE(FAILED, "[Check][AnalyzeFile]analyze file does not exist[%s]", json_file_name_.c_str());
    return PARAM_INVALID;
  }
@@ -221,7 +221,7 @@ ge::Status Analyzer::SaveAnalyzerDataToFile(uint64_t session_id, uint64_t graph_
  try {
    json_file_ << jsn.dump(kJsonDumpLevel) << std::endl;
  } catch (nlohmann::detail::type_error &e) {
    GELOGE(FAILED, "analyzer file [%s] failed because [%s]", json_file_name_.c_str(), e.what());
    GELOGE(FAILED, "[Json.dump][GraphInfo]json.dump to analyze file [%s] failed because [%s], session_id:%lu, graph_id:%lu", json_file_name_.c_str(), e.what(), session_id, graph_id);
    ret_failed = true;
  }
  json_file_.close();
@@ -229,7 +229,7 @@ ge::Status Analyzer::SaveAnalyzerDataToFile(uint64_t session_id, uint64_t graph_
 }
 ge::Status Analyzer::DoAnalyze(DataInfo &data_info) {
  GELOGD("start to do analyzer!");
  GELOGD("start to do analyzer process!");
  auto pnode = data_info.node_ptr;
  GE_CHECK_NOTNULL(pnode);
@@ -241,7 +241,7 @@ ge::Status Analyzer::DoAnalyze(DataInfo &data_info) {
  GE_CHECK_NOTNULL(graph_info);
  auto status = SaveOpInfo(desc, data_info, graph_info);
  if (status != SUCCESS) {
    GELOGE(status, "save op info failed!");
    GELOGE(status, "[Check][SaveOpInfo]save op info: desc_name [%s] desc_type [%s] failed!", desc->GetName().c_str(), desc->GetType().c_str());
    return FAILED;
  }
  // create json file
--- a/ge/client/ge_api.cc
+++ b/ge/client/ge_api.cc
@@ -32,6 +32,7 @@
 #include "graph/common/ge_call_wrapper.h"
 #include "register/op_registry.h"
 #include "common/ge/tbe_plugin_manager.h"
 #include "common/util/error_manager/error_manager.h"
 #include "toolchain/plog.h"
 using domi::OpRegistry;
@@ -78,12 +79,21 @@ Status CheckOptionsValid(const std::map<string, string> &options) {
 // Initialize GE, prepare for execution, call GELib::Initialize
 Status GEInitializeImpl(const std::map<string, string> &options) {
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  GELOGT(TRACE_INIT, "GEInitialize start");
  std::string path_base = ge::GELib::GetPath();
  auto ret = ErrorManager::GetInstance().Init(path_base);
  if (ret != SUCCESS) {
    GELOGE(GE_CLI_INIT_FAILED, "ErrorManager init fail");
    return ret;
  }
  // 0.check init status
  if (g_ge_initialized) {
    GELOGW("GEInitialize is called more than once");
    return SUCCESS;
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOpsProtoInit);
  // Load OpsProto lib plugin
  std::string opsproto_path;
  GetOpsProtoPath(opsproto_path);
@@ -98,6 +108,7 @@ Status GEInitializeImpl(const std::map<string, string> &options) {
    return FAILED;
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOther);
  // check options is valid
  GE_TIMESTAMP_START(CheckOptionsValid);
  if (CheckOptionsValid(options) != SUCCESS) {
@@ -105,13 +116,15 @@ Status GEInitializeImpl(const std::map<string, string> &options) {
  }
  GE_TIMESTAMP_END(CheckOptionsValid, "GEInitialize::CheckOptionsValid");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOpsProtoInit);
  GE_TIMESTAMP_START(InitPreparation);
  TBEPluginManager::Instance().InitPreparation(options);
  GE_TIMESTAMP_END(InitPreparation, "GEInitialize::InitPreparation");
  // call Initialize
  GELOGT(TRACE_RUNNING, "Initializing environment");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOther);
  GE_TIMESTAMP_START(GELibInitialize);
  Status ret = ge::GELib::Initialize(options);
  ret = ge::GELib::Initialize(options);
  GE_TIMESTAMP_END(GELibInitialize, "GEInitialize::GELibInitialize");
  if (ret != SUCCESS) {
    GELOGE(GE_CLI_INIT_FAILED, "geInitialize failed, error code = %u", ret);
@@ -130,6 +143,7 @@ Status GEInitializeImpl(const std::map<string, string> &options) {
 // Initialize GE, prepare for execution, call GELib::Initialize
 Status GEInitialize(const std::map<string, string> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOther);
  if (DlogReportInitialize() != SUCCESS) {
    GELOGW("Dlog report device log initialize failed.");
  }
@@ -137,6 +151,7 @@ Status GEInitialize(const std::map<string, string> &options) {
 }
 Status GEInitialize(const std::map<AscendString, AscendString> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOther);
  std::map<std::string, std::string> str_options;
  for (auto &option : options) {
    if (option.first.GetString() == nullptr || option.second.GetString() == nullptr) {
@@ -156,7 +171,10 @@ Status GEInitialize(const std::map<AscendString, AscendString> &options) {
 // GE finalize, releasing all resources
 Status GEFinalize() {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kFinalize, ErrorMessage::kFinalize);
  GELOGT(TRACE_INIT, "GEFinalize start");
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  // check init status
  if (!g_ge_initialized) {
    GELOGW("GEFinalize is called before GEInitialize");
@@ -202,9 +220,20 @@ Status GEFinalize() {
  return ret;
 }
 std::string GEGetErrorMsg() {
  return ErrorManager::GetInstance().GetErrorMessage();
 }
 std::string GEGetWarningMsg() {
  return ErrorManager::GetInstance().GetWarningMessage();
 }
 // Initialize session，which calls innerSession
 Session::Session(const std::map<string, string> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOther);
  GELOGT(TRACE_INIT, "Session Constructor start");
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  // check init status
  sessionId_ = 0;
  if (!g_ge_initialized) {
@@ -234,7 +263,10 @@ Session::Session(const std::map<string, string> &options) {
 }
 Session::Session(const std::map<AscendString, AscendString> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOther);
  GELOGT(TRACE_INIT, "Session Constructor start");
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  // check init status
  sessionId_ = 0;
  if (!g_ge_initialized) {
@@ -275,6 +307,7 @@ Session::Session(const std::map<AscendString, AscendString> &options) {
 // session destructor
 Session::~Session() {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kFinalize, ErrorMessage::kFinalize);
  GELOGT(TRACE_INIT, "Session Destructor start");
  // 0.check init status
  if (!g_ge_initialized) {
@@ -310,12 +343,16 @@ Session::~Session() {
 }
 Status Session::AddGraph(uint32_t graph_id, const Graph &graph) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  std::map<std::string, std::string> options;
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  return AddGraph(graph_id, graph, options);
 }
 Status Session::AddGraph(uint32_t graph_id, const Graph &graph, const std::map<std::string, std::string> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGT(TRACE_INIT, "Start to add graph in Session. graph_id: %u, session_id: %lu.", graph_id, sessionId_);
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if (instance_ptr == nullptr || !instance_ptr->InitFlag()) {
    GELOGE(GE_CLI_GE_NOT_INITIALIZED, "AddGraph failed in Session.");
@@ -333,7 +370,9 @@ Status Session::AddGraph(uint32_t graph_id, const Graph &graph, const std::map<s
 Status Session::AddGraph(uint32_t graph_id, const Graph &graph,
                         const std::map<AscendString, AscendString> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGT(TRACE_INIT, "Start to add graph in Session. graph_id: %u, session_id: %lu.", graph_id, sessionId_);
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if (instance_ptr == nullptr || !instance_ptr->InitFlag()) {
    GELOGE(GE_CLI_GE_NOT_INITIALIZED, "AddGraph failed in Session.");
@@ -360,13 +399,17 @@ Status Session::AddGraph(uint32_t graph_id, const Graph &graph,
 }
 Status Session::AddGraphWithCopy(uint32_t graph_id, const Graph &graph) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  std::map<AscendString, AscendString> options;
  return AddGraphWithCopy(graph_id, graph, options);
 }
 Status Session::AddGraphWithCopy(uint32_t graph_id, const Graph &graph,
                                 const std::map<AscendString, AscendString> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGT(TRACE_INIT, "Start to add graph in Session. graph_id: %u, session_id: %lu.", graph_id, sessionId_);
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if (instance_ptr == nullptr || !instance_ptr->InitFlag()) {
    GELOGE(GE_CLI_GE_NOT_INITIALIZED, "AddGraph failed in Session.");
@@ -387,8 +430,10 @@ Status Session::AddGraphWithCopy(uint32_t graph_id, const Graph &graph,
 }
 Status Session::RemoveGraph(uint32_t graph_id) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGT(TRACE_INIT, "Session RemoveGraph start");
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  // call RemoveGraph
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if (!instance_ptr || !instance_ptr->InitFlag()) {
@@ -455,8 +500,10 @@ void PrintOutputResult(std::vector<Tensor> &outputs) {
 }
 Status Session::RunGraph(uint32_t graph_id, const std::vector<Tensor> &inputs, std::vector<Tensor> &outputs) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGT(TRACE_INIT, "Session RunGraph start");
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  std::vector<Tensor> graph_inputs = inputs;
  // call RunGraph
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
@@ -483,10 +530,12 @@ Status Session::RunGraph(uint32_t graph_id, const std::vector<Tensor> &inputs, s
 }
 Status Session::RegisterCallBackFunc(const std::string &key, const pCallBackFunc &callback) {
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  return ge::GELib::GetInstance()->SessionManagerObj().RegisterCallBackFunc(sessionId_, key, callback);
 }
 Status Session::RegisterCallBackFunc(const char *key, const session::pCallBackFunc &callback) {
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  std::string str_key;
  if (key != nullptr) {
    str_key = key;
@@ -495,6 +544,8 @@ Status Session::RegisterCallBackFunc(const char *key, const session::pCallBackFu
 }
 Status Session::BuildGraph(uint32_t graph_id, const std::vector<InputTensorInfo> &inputs) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if (instance_ptr == nullptr || !instance_ptr->InitFlag()) {
    GELOGE(GE_CLI_GE_NOT_INITIALIZED, "SessionConstructor failed");
@@ -511,6 +562,8 @@ Status Session::BuildGraph(uint32_t graph_id, const std::vector<InputTensorInfo>
 Status Session::RunGraphAsync(uint32_t graph_id, const std::vector<InputTensorInfo> &inputs,
                              RunAsyncCallback callback) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
  ErrorManager::GetInstance().GenWorkStreamIdBySessionGraph(sessionId_, graph_id);
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if (instance_ptr == nullptr || !instance_ptr->InitFlag()) {
    GELOGE(GE_CLI_GE_NOT_INITIALIZED, "SessionConstructor failed");
@@ -529,6 +582,8 @@ Status Session::RunGraphAsync(uint32_t graph_id, const std::vector<InputTensorIn
 }
 Status Session::GetVariables(const std::vector<std::string> &var_names, std::vector<Tensor> &var_values) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  auto instance_ptr = ge::GELib::GetInstance();
  if (instance_ptr == nullptr || !instance_ptr->InitFlag()) {
    GELOGE(GE_CLI_GE_NOT_INITIALIZED, "SessionConstructor failed");
@@ -544,6 +599,8 @@ Status Session::GetVariables(const std::vector<std::string> &var_names, std::vec
 }
 Status Session::GetVariables(const std::vector<AscendString> &var_names, std::vector<Tensor> &var_values) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
  ErrorManager::GetInstance().GenWorkStreamIdDefault();
  auto instance_ptr = ge::GELib::GetInstance();
  if (instance_ptr == nullptr || !instance_ptr->InitFlag()) {
    GELOGE(GE_CLI_GE_NOT_INITIALIZED, "SessionConstructor failed");
--- a/ge/common/CMakeLists.txt
+++ b/ge/common/CMakeLists.txt
@@ -54,7 +54,7 @@ set(SRC_LIST
    "util.cc"
    "properties_manager.cc"
    "types.cc"
    "model_parser/base.cc"
    "model_parser/model_parser.cc"
    "kernel_store.cc"
    "tbe_kernel_store.cc"
    "cust_aicpu_kernel_store.cc"
--- a/ge/common/cust_aicpu_kernel_store.cc
+++ b/ge/common/cust_aicpu_kernel_store.cc
@@ -25,7 +25,7 @@ void CustAICPUKernelStore::AddCustAICPUKernel(const CustAICPUKernelPtr &kernel)
 }
 void CustAICPUKernelStore::LoadCustAICPUKernelBinToOpDesc(const std::shared_ptr<ge::OpDesc> &op_desc) const {
  GELOGD("LoadCustAICPUKernelBinToOpDesc in");
  GELOGD("LoadCustAICPUKernelBinToOpDesc in.");
  if (op_desc != nullptr) {
    auto kernel_bin = FindKernel(op_desc->GetName());
    if (kernel_bin != nullptr) {
@@ -34,6 +34,6 @@ void CustAICPUKernelStore::LoadCustAICPUKernelBinToOpDesc(const std::shared_ptr<
      GELOGI("Load cust aicpu kernel:%s, %zu", kernel_bin->GetName().c_str(), kernel_bin->GetBinDataSize());
    }
  }
  GELOGD("LoadCustAICPUKernelBinToOpDesc success");
  GELOGD("LoadCustAICPUKernelBinToOpDesc success.");
 }
 }  // namespace ge
--- a/ge/common/dump/dump_manager.cc
+++ b/ge/common/dump/dump_manager.cc
@@ -22,6 +22,7 @@ namespace {
 const char *const kDumpOFF = "OFF";
 const char *const kDumpoff = "off";
 const char *const kDumpOn = "on";
 const uint64_t kInferSessionId = 0;
 }  // namespace
 namespace ge {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY DumpManager &DumpManager::GetInstance() {
@@ -30,15 +31,14 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY DumpManager &DumpManager::GetIn
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status DumpManager::SetDumpConf(const DumpConfig &dump_config) {
  std::lock_guard<std::mutex> lock(mutex_);
  dump_properties_.ClearDumpPropertyValue();
  dump_properties_.ClearDumpInfo();
  DumpProperties dump_properties;
  std::string dump_status;
  std::string dump_path;
  std::string dump_mode;
  std::string dump_op_switch;
  if (dump_config.dump_status.empty()) {
    dump_properties_map_.emplace(kInferSessionId, dump_properties);
    GELOGI("Dump does not open");
    return SUCCESS;
  }
@@ -46,14 +46,16 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status DumpManager::SetDumpConf
  dump_status = dump_config.dump_status;
  GELOGI("Dump status is %s", dump_status.c_str());
  if (dump_config.dump_status == kDumpoff || dump_config.dump_status == kDumpOFF) {
    dump_properties_.ClearDumpPropertyValue();
    dump_properties.ClearDumpPropertyValue();
    dump_properties_map_.emplace(kInferSessionId, dump_properties);
    return SUCCESS;
  }
  dump_properties_.SetDumpStatus(dump_status);
  dump_properties.SetDumpStatus(dump_status);
  dump_op_switch = dump_config.dump_op_switch;
  dump_properties_.SetDumpOpSwitch(dump_op_switch);
  dump_properties.SetDumpOpSwitch(dump_op_switch);
  if (dump_op_switch == kDumpoff && dump_config.dump_list.empty()) {
    dump_properties_map_.emplace(kInferSessionId, dump_properties);
    GELOGE(PARAM_INVALID, "Dump list is invalid,dump_op_switch is %s", dump_op_switch.c_str());
    return PARAM_INVALID;
  }
@@ -67,15 +69,15 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status DumpManager::SetDumpConf
        GELOGI("Dump layer is %s in model", layer.c_str());
        dump_layers.insert(layer);
      }
      dump_properties_.AddPropertyValue(model_name, dump_layers);
      dump_properties.AddPropertyValue(model_name, dump_layers);
    }
    if (dump_op_switch == kDumpOn) {
      GELOGI("Start to dump model and single op,dumo op switch is %s", dump_op_switch.c_str());
      GELOGI("Start to dump model and single op,dump op switch is %s", dump_op_switch.c_str());
    } else {
      GELOGI("Only dump model,dump op switch is %s", dump_op_switch.c_str());
    }
  } else {
    GELOGI("Only dump single op,dumo op switch is %s", dump_op_switch.c_str());
    GELOGI("Only dump single op,dump op switch is %s", dump_op_switch.c_str());
  }
  dump_path = dump_config.dump_path;
@@ -89,27 +91,39 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status DumpManager::SetDumpConf
  }
  dump_path = dump_path + CurrentTimeInStr() + "/";
  GELOGI("Dump path is %s", dump_path.c_str());
  dump_properties_.SetDumpPath(dump_path);
  dump_properties.SetDumpPath(dump_path);
  dump_mode = dump_config.dump_mode;
  GELOGI("Dump mode is %s", dump_mode.c_str());
  dump_properties_.SetDumpMode(dump_mode);
  dump_properties.SetDumpMode(dump_mode);
  dump_properties_map_.emplace(kInferSessionId, dump_properties);
  return SUCCESS;
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY const DumpProperties &DumpManager::GetDumpProperties() {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY const DumpProperties &DumpManager::GetDumpProperties(
  uint64_t session_id) {
  std::lock_guard<std::mutex> lock(mutex_);
  return dump_properties_;
  auto iter = dump_properties_map_.find(session_id);
  if (iter != dump_properties_map_.end()) {
    return iter->second;
  }
  static DumpProperties default_properties;
  return default_properties;
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void DumpManager::SetModelName(const std::string &model_name) {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void DumpManager::AddDumpProperties(
  uint64_t session_id, const DumpProperties &dump_properties) {
  std::lock_guard<std::mutex> lock(mutex_);
  model_name_ = model_name;
  dump_properties_map_.emplace(session_id, dump_properties);
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY const std::string &DumpManager::GetModelName() {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void DumpManager::RemoveDumpProperties(uint64_t session_id) {
  std::lock_guard<std::mutex> lock(mutex_);
  return model_name_;
  auto iter = dump_properties_map_.find(session_id);
  if (iter != dump_properties_map_.end()) {
    dump_properties_map_.erase(iter);
  }
 }
 }  // namespace ge
--- a/ge/common/dump/dump_manager.h
+++ b/ge/common/dump/dump_manager.h
@@ -28,14 +28,14 @@ class DumpManager {
  static DumpManager &GetInstance();
  Status SetDumpConf(const DumpConfig &dump_config);
  const DumpProperties &GetDumpProperties();
  void SetModelName(const std::string &model_name);
  const std::string &GetModelName();
  const DumpProperties &GetDumpProperties(uint64_t session_id);
  const std::map<uint64_t, DumpProperties> &GetDumpPropertiesMap() { return dump_properties_map_; }
  void AddDumpProperties(uint64_t session_id, const DumpProperties &dump_properties);
  void RemoveDumpProperties(uint64_t session_id);
 private:
  DumpProperties dump_properties_;
  std::mutex mutex_;
  std::string model_name_;
  std::map<uint64_t, DumpProperties> dump_properties_map_;
 };
 }  // namespace ge
 #endif  // GE_COMMON_DUMP_DUMP_MANAGER_H_
--- a/ge/common/dump/dump_op.cc
+++ b/ge/common/dump/dump_op.cc
@@ -219,9 +219,9 @@ Status DumpOp::LaunchDumpOp() {
  op_mapping_info.set_dump_path(dump_path);
  op_mapping_info.set_flag(kAicpuLoadFlag);
  op_mapping_info.set_dump_step(dump_properties_.GetDumpStep());
  if (!dynamic_model_name_.empty()) {
  op_mapping_info.set_model_id(dynamic_model_id_);
  if (!dynamic_model_name_.empty() && dump_properties_.IsDumpOpen()) {
    op_mapping_info.set_model_name(dynamic_model_name_);
    op_mapping_info.set_model_id(dynamic_model_id_);
  }
  SetOpMappingLoopAddr(global_step_, loop_per_iter_, loop_cond_, op_mapping_info);
  GELOGI("Dump step is %s ,dump path is %s ,in Launch dump op", dump_properties_.GetDumpStep().c_str(),
@@ -253,7 +253,7 @@ Status DumpOp::LaunchDumpOp() {
    }
    op_mapping_info.mutable_task()->Add(std::move(task));
  }
  if (dump_properties_.GetDumpMode() == kDumpAll) {
  if (dump_properties_.GetDumpMode() == kDumpAll || dump_properties_.IsOpDebugOpen()) {
    auto ret = DumpOutput(task);
    if (ret != SUCCESS) {
      GELOGE(ret, "Dump output failed when in dumping all");
--- a/ge/common/dump/dump_properties.cc
+++ b/ge/common/dump/dump_properties.cc
@@ -122,6 +122,8 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void DumpProperties::ClearDumpI
  dump_path_.clear();
  dump_step_.clear();
  dump_mode_.clear();
  dump_op_switch_.clear();
  dump_status_.clear();
  is_op_debug_ = false;
  op_debug_mode_ = 0;
 }
@@ -201,7 +203,7 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY const std::string &DumpProperti
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void DumpProperties::SetDumpOpSwitch(
    const std::string dump_op_switch) {
    const std::string &dump_op_switch) {
  dump_op_switch_ = dump_op_switch;
 }
@@ -230,6 +232,8 @@ void DumpProperties::CopyFrom(const DumpProperties &other) {
    dump_path_ = other.dump_path_;
    dump_step_ = other.dump_step_;
    dump_mode_ = other.dump_mode_;
    dump_status_ = other.dump_status_;
    dump_op_switch_ = other.dump_op_switch_;
    model_dump_properties_map_ = other.model_dump_properties_map_;
    is_op_debug_ = other.is_op_debug_;
--- a/ge/common/dump/dump_properties.h
+++ b/ge/common/dump/dump_properties.h
@@ -65,7 +65,7 @@ class DumpProperties {
  const std::string &GetDumpStatus() const;
  void SetDumpOpSwitch(const std::string dump_op_switch);
  void SetDumpOpSwitch(const std::string &dump_op_switch);
  const std::string &GetDumpOpSwitch() const;
@@ -81,11 +81,11 @@ class DumpProperties {
  const std::string &GetEnableDumpDebug() const {return enable_dump_debug_;}
 private:
  void CopyFrom(const DumpProperties &other);
  void SetDumpDebugOptions();
  std::string enable_dump_;
  std::string enable_dump_debug_;
--- a/ge/common/dump/opdebug_register.cc
+++ b/ge/common/dump/opdebug_register.cc
@@ -0,0 +1,148 @@
 /**
 * Copyright 2020 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.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
 #include "opdebug_register.h"
 namespace {
 const size_t kOpDebugMemorySize = 2048UL;
 const size_t kDebugP2pSize = 8UL;
 }  // namespace
 namespace ge {
 OpdebugRegister::~OpdebugRegister() {}
 Status OpdebugRegister::RegisterDebugForModel(rtModel_t model_handle, uint32_t op_debug_mode, DataDumper &data_dumper) {
  GELOGD("Start to register debug for model in overflow");
  auto ret = MallocMemForOpdebug();
  if (ret != SUCCESS) {
    GELOGE(ret, "Malloc memory for opdebug in model overflow failed ,ret:0x%X", ret);
    return ret;
  }
  uint32_t debug_stream_id = 0;
  uint32_t debug_task_id = 0;
  auto rt_ret = rtDebugRegister(model_handle, op_debug_mode, op_debug_addr_, &debug_stream_id, &debug_task_id);
  if (rt_ret != RT_ERROR_NONE) {
    GELOGE(RT_FAILED, "rtDebugRegister error, ret: 0x%X", rt_ret);
    return RT_ERROR_TO_GE_STATUS(rt_ret);
  }
  GELOGD("debug_task_id:%u, debug_stream_id:%u in model overflow", debug_task_id, debug_stream_id);
  data_dumper.SaveOpDebugId(debug_task_id, debug_stream_id, p2p_debug_addr_, true);
  return SUCCESS;
 }
 void OpdebugRegister::UnregisterDebugForModel(rtModel_t model_handle) {
  rtError_t rt_ret = RT_ERROR_NONE;
  if (model_handle != nullptr) {
    GELOGD("start to call rtDebugUnRegister in model overflow.");
    rt_ret = rtDebugUnRegister(model_handle);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGW("rtDebugUnRegister failed, ret: 0x%X", rt_ret);
    }
  }
  if (op_debug_addr_ != nullptr) {
    rt_ret = rtFree(op_debug_addr_);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGW("rtFree failed, ret: 0x%X", rt_ret);
    }
    op_debug_addr_ = nullptr;
  }
  if (p2p_debug_addr_ != nullptr) {
    rt_ret = rtFree(p2p_debug_addr_);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGW("rtFree failed, ret: 0x%X", rt_ret);
    }
    p2p_debug_addr_ = nullptr;
  }
  return;
 }
 Status OpdebugRegister::RegisterDebugForStream(rtStream_t stream, uint32_t op_debug_mode, DataDumper &data_dumper) {
  GELOGD("Start to register debug for stream in stream overflow");
  auto ret = MallocMemForOpdebug();
  if (ret != SUCCESS) {
    GELOGE(ret, "Malloc memory for opdebug in stream overflow ,ret:0x%X", ret);
    return ret;
  }
  uint32_t debug_stream_id = 0;
  uint32_t debug_task_id = 0;
 #ifdef ONLY_COMPILE_OPEN_SRC
  auto rt_ret = rtDebugRegisterForStream(stream, op_debug_mode, op_debug_addr_, &debug_stream_id, &debug_task_id);
  if (rt_ret != RT_ERROR_NONE) {
    GELOGE(RT_FAILED, "rtDebugRegisterForStream error, ret: 0x%X", rt_ret);
    return RT_ERROR_TO_GE_STATUS(rt_ret);
  }
 #endif
  GELOGD("debug_task_id:%u, debug_stream_id:%u in stream overflow.", debug_task_id, debug_stream_id);
  data_dumper.SaveOpDebugId(debug_task_id, debug_stream_id, p2p_debug_addr_, true);
  return SUCCESS;
 }
 void OpdebugRegister::UnregisterDebugForStream(rtStream_t stream) {
  rtError_t rt_ret = RT_ERROR_NONE;
 #ifdef ONLY_COMPILE_OPEN_SRC
  if (stream != nullptr) {
    GELOGD("start call rtDebugUnRegisterForStream in unknown shape over flow.");
    rt_ret = rtDebugUnRegisterForStream(stream);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGW("rtDebugUnRegisterForStream failed, ret: 0x%X", rt_ret);
    }
  }
 #endif
  if (op_debug_addr_ != nullptr) {
    rt_ret = rtFree(op_debug_addr_);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGW("rtFree failed, ret: 0x%X", rt_ret);
    }
    op_debug_addr_ = nullptr;
  }
  if (p2p_debug_addr_ != nullptr) {
    rt_ret = rtFree(p2p_debug_addr_);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGW("rtFree failed, ret: 0x%X", rt_ret);
    }
    p2p_debug_addr_ = nullptr;
  }
  return;
 }
 Status OpdebugRegister::MallocMemForOpdebug() {
  rtError_t rt_ret = rtMalloc(&op_debug_addr_, kOpDebugMemorySize, RT_MEMORY_DDR);
  if (rt_ret != RT_ERROR_NONE) {
    GELOGE(RT_FAILED, "rtMalloc error, ret: 0x%X", rt_ret);
    return RT_ERROR_TO_GE_STATUS(rt_ret);
  }
  uint64_t debug_addrs_tmp = static_cast<uint64_t>(reinterpret_cast<uintptr_t>(op_debug_addr_));
  // For data dump, aicpu needs the pointer to pointer that save the real debug address.
  rt_ret = rtMalloc(&p2p_debug_addr_, kDebugP2pSize, RT_MEMORY_HBM);
  if (rt_ret != RT_ERROR_NONE) {
    GELOGE(RT_FAILED, "rtMalloc error, ret: 0x%X", rt_ret);
    return RT_ERROR_TO_GE_STATUS(rt_ret);
  }
  rt_ret = rtMemcpy(p2p_debug_addr_, sizeof(uint64_t), &debug_addrs_tmp, sizeof(uint64_t), RT_MEMCPY_HOST_TO_DEVICE);
  if (rt_ret != RT_ERROR_NONE) {
    GELOGE(RT_FAILED, "rtMemcpy to p2p_addr error: 0x%X", rt_ret);
    return RT_ERROR_TO_GE_STATUS(rt_ret);
  }
  return SUCCESS;
 }
 }  // namespace ge
--- a/ge/common/dump/opdebug_register.h
+++ b/ge/common/dump/opdebug_register.h
@@ -0,0 +1,44 @@
 /**
 * Copyright 2020 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.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
 #ifndef GE_COMMON_DUMP_OPDEBUG_REGISTER_H_
 #define GE_COMMON_DUMP_OPDEBUG_REGISTER_H_
 #include <map>
 #include "common/debug/ge_log.h"
 #include "common/debug/log.h"
 #include "graph/load/model_manager/data_dumper.h"
 namespace ge {
 class OpdebugRegister {
 public:
  OpdebugRegister() = default;
  ~OpdebugRegister();
  Status RegisterDebugForModel(rtModel_t model_handle, uint32_t op_debug_mode, DataDumper &data_dumper);
  void UnregisterDebugForModel(rtModel_t model_handle);
  Status RegisterDebugForStream(rtStream_t stream, uint32_t op_debug_mode, DataDumper &data_dumper);
  void UnregisterDebugForStream(rtStream_t stream);
 private:
  Status MallocMemForOpdebug();
  void *op_debug_addr_ = nullptr;
  void *p2p_debug_addr_ = nullptr;
 };
 }  // namespace ge
 #endif  // GE_COMMON_DUMP_OPDEBUG_REGISTER_H_
--- a/ge/common/formats/format_transfers/datatype_transfer.cc
+++ b/ge/common/formats/format_transfers/datatype_transfer.cc
@@ -111,7 +111,7 @@ Status CastKernel(const CastArgs &args, uint8_t *dst, const size_t data_size, co
  };
  auto it = transfer_handle.find(trans_mode);
  if (it == transfer_handle.end()) {
    return UNSUPPORTED;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  } else {
    return (it->second)(args, dst, data_size);
  }
@@ -127,8 +127,8 @@ Status DataTypeTransfer::TransDataType(const CastArgs &args, TransResult &result
    std::string error = "Failed to trans data from datatype " +
        FmtToStr(TypeUtils::DataTypeToSerialString(args.src_data_type)) + " to " +
        FmtToStr(TypeUtils::DataTypeToSerialString(args.dst_data_type)) + " , it is not supported.";
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_DATATYPE_INVALID, error.c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  auto trans_mode = iter->second;
@@ -136,14 +136,14 @@ Status DataTypeTransfer::TransDataType(const CastArgs &args, TransResult &result
  if (size <= 0) {
    std::string error = "Failed to calc size from data type" +
        FmtToStr(TypeUtils::DataTypeToSerialString(args.dst_data_type)) + ", it is not supported.";
    GE_ERRORLOG_AND_ERRORMSG(PARAM_INVALID, error.c_str());
    return PARAM_INVALID;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_DATATYPE_INVALID, error.c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (args.src_data_size > static_cast<size_t>(SIZE_MAX / size)) {
    std::string error = "args.src_data_size" + FmtToStr(args.src_data_size) +
        " or data type size" + FmtToStr(size) + " is too big";
    GE_ERRORLOG_AND_ERRORMSG(PARAM_INVALID, error.c_str());
    return PARAM_INVALID;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_PARAM_INVALID, error.c_str());
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  size_t total_size = static_cast<size_t>(args.src_data_size * size);
  result.length = total_size;
@@ -154,8 +154,8 @@ Status DataTypeTransfer::TransDataType(const CastArgs &args, TransResult &result
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to alloc the memory for dst buf %zu, data size %zu", total_size, args.src_data_size);
    return OUT_OF_MEMORY;
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to alloc the memory for dst buf %zu, data size %zu", total_size, args.src_data_size);
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  if (CastKernel(args, dst.get(), args.src_data_size, trans_mode) != SUCCESS) {
@@ -163,8 +163,8 @@ Status DataTypeTransfer::TransDataType(const CastArgs &args, TransResult &result
        FmtToStr(TypeUtils::DataTypeToSerialString(args.src_data_type)) + " to " +
        FmtToStr(TypeUtils::DataTypeToSerialString(args.dst_data_type)) + ", data size is " +
        FmtToStr(std::to_string(args.src_data_size));
    GE_ERRORLOG_AND_ERRORMSG(INTERNAL_ERROR, error.c_str());
    return INTERNAL_ERROR;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_INTERNAL_ERROR, error.c_str());
    return ACL_ERROR_GE_INTERNAL_ERROR;
  }
  result.data = dst;
  return SUCCESS;
--- a/ge/common/formats/format_transfers/format_transfer_c1hwncoc0_hwcn.cc
+++ b/ge/common/formats/format_transfers/format_transfer_c1hwncoc0_hwcn.cc
@@ -39,22 +39,22 @@ Status CheckArgsForC1hwncoc0ToHwcn(const TransArgs &args) {
    std::string error = "Dose not support trans format from " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  if (!CheckDataTypeSupported(args.src_data_type)) {
    std::string error = "Failed to trans shape from NC1HWNCoC0 to HWCN, invalid data type" +
        FmtToStr(TypeUtils::DataTypeToSerialString(args.src_data_type));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_DATATYPE_INVALID, error.c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShapeValid(src_shape, kC1hwncoc0DimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check src shape %s", ShapeToString(src_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s", ShapeToString(src_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (!CheckShapeValid(dst_shape, kHwcnDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s.", ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto cube_size = GetCubeSizeByDataType(args.src_data_type);
  if (src_shape.at(kC1hwncoc0C1) != (dst_shape.at(kHwcnC) - 1) / cube_size + 1 ||
@@ -63,8 +63,8 @@ Status CheckArgsForC1hwncoc0ToHwcn(const TransArgs &args) {
      src_shape.at(kC1hwncoc0C0) != cube_size) {
    std::string error = "Failed to check relationship between src and dst shape, src shape" +
        FmtToStr(ShapeToString(src_shape)) + ", dst shape" + FmtToStr(ShapeToString(dst_shape));
    GE_ERRORLOG_AND_ERRORMSG(PARAM_INVALID, error.c_str());
    return PARAM_INVALID;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_SHAPE_INVALID, error.c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
@@ -73,10 +73,10 @@ Status CheckArgsForC1hwncoc0ToHwcn(const TransArgs &args) {
 Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, int size, int64_t total_size) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), total_size, ShapeToString(args.dst_shape).c_str());
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto h = args.src_shape.at(kC1hwncoc0H);
@@ -114,12 +114,12 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, int size
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR,
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                   "Failed to copy data from C1HWNCoC0[%ld, %ld, %ld, %ld, %ld, %ld] offset %ld to "
                   "HWCN[%ld, %ld, %ld, %ld] offset %ld, err-code %d",
                   c1_idx, h_idx, w_idx, n_idx, co_idx, c0_idx, src_offset, h_idx, w_idx, c_idx, n_idx, dst_offset,
                   ret);
            return INTERNAL_ERROR;
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
      }
@@ -132,8 +132,9 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, int size
 }  // namespace
 Status FormatTransferC1hwncoc0Hwcn::TransFormat(const TransArgs &args, TransResult &result) {
  if (CheckArgsForC1hwncoc0ToHwcn(args) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckArgsForC1hwncoc0ToHwcn(args);
  if (ret != SUCCESS) {
    return ret;
  }
  int size = GetSizeByDataType(args.src_data_type);
  int64_t total_size = GetItemNumByShape(args.dst_shape) * size;
@@ -143,26 +144,27 @@ Status FormatTransferC1hwncoc0Hwcn::TransFormat(const TransArgs &args, TransResu
      result.length = static_cast<size_t>(total_size);
      return SUCCESS;
    }
    GELOGE(INTERNAL_ERROR, "Get %ld total size from dst shape %s, src shape %s", total_size,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Get %ld total size from dst shape %s, src shape %s.", total_size,
           ShapeToString(args.dst_shape).c_str(), ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from C1HWNCoC0 to HWCN, src shape %s, data type %s, dst shape %s, memory size %ld",
  GELOGD("Begin to trans format from C1HWNCoC0 to HWCN, src shape %s, data type %s, dst shape %s, memory size %ld.",
         ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
         ShapeToString(args.dst_shape).c_str(), total_size);
  if (GetDstDataAfterTrans(args, result, size, total_size) != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
  ret = GetDstDataAfterTrans(args, result, size, total_size);
  if (ret != SUCCESS) {
    GELOGE(ret, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
           ShapeToString(args.dst_shape).c_str(), total_size);
    return INTERNAL_ERROR;
    return ret;
  }
  return SUCCESS;
 }
 Status FormatTransferC1hwncoc0Hwcn::TransShape(Format src_format, const std::vector<int64_t> &src_shape,
                                               DataType data_type, Format dst_format, std::vector<int64_t> &dst_shape) {
  GELOGD("The shape derivation from C1HWNCoC0 to HWCN is not unique. Trans shape in this direction is not supported");
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  GELOGD("The shape derivation from C1HWNCoC0 to HWCN is not unique. Trans shape in this direction is not supported.");
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferC1hwncoc0Hwcn, FORMAT_C1HWNCoC0, FORMAT_HWCN)
--- a/ge/common/formats/format_transfers/format_transfer_dhwcn_fracz3D.cc
+++ b/ge/common/formats/format_transfers/format_transfer_dhwcn_fracz3D.cc
@@ -32,7 +32,7 @@ Status TransShapeToFz(int64_t d, int64_t n, int64_t c, int64_t h, int64_t w, Dat
                      std::vector<int64_t> &dst_shape) {
  auto c0 = GetCubeSizeByDataType(data_type);
  if (c0 < 0) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  auto c1 = Ceil(c, c0);
@@ -50,7 +50,7 @@ Status TransShapeToFz(int64_t d, int64_t n, int64_t c, int64_t h, int64_t w, Dat
 Status TransShapeDhwckToFz3D(const std::vector<int64_t> &src_shape, DataType data_type,
                             std::vector<int64_t> &dst_shape) {
  if (!CheckShapeValid(src_shape, kDhwcnDimsNum)) {
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto d = src_shape.at(kDhwcnD);
  auto h = src_shape.at(kDhwcnH);
@@ -62,7 +62,7 @@ Status TransShapeDhwckToFz3D(const std::vector<int64_t> &src_shape, DataType dat
 }
 Status TransFormatDhwckToFz3D(const TransArgs &args, TransResult &result) {
  if (!CheckShapeValid(args.src_shape, kDhwcnDimsNum)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  int64_t d = args.src_shape[kDhwcnD];
  int64_t h = args.src_shape[kDhwcnH];
@@ -94,10 +94,10 @@ Status TransFormatDhwckToFz3D(const TransArgs &args, TransResult &result) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  for (int64_t di = 0; di < d; di++) {
@@ -122,9 +122,9 @@ Status TransFormatDhwckToFz3D(const TransArgs &args, TransResult &result) {
                               args.data + src_idx * data_size, static_cast<size_t>(data_size));
              }
              if (ret != EOK) {
                GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
                GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
                       dst_offset, ret, pad_zero);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
              }
            }
          }
@@ -149,28 +149,28 @@ Status FormatTransferDhwcnFractalZ3D::TransFormat(const TransArgs &args, TransRe
    return ret;
  }
  if (!IsTransShapeDstCorrect(args, expect_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (args.src_format == FORMAT_DHWCN && args.dst_format == FORMAT_FRACTAL_Z_3D) {
    return TransFormatDhwckToFz3D(args, result);
  }
  return UNSUPPORTED;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 Status FormatTransferDhwcnFractalZ3D::TransShape(Format src_format, const std::vector<int64_t> &src_shape,
                                                 DataType data_type, Format dst_format,
                                                 std::vector<int64_t> &dst_shape) {
  if (CheckDataTypeSupport(data_type) != SUCCESS) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (src_format == FORMAT_DHWCN && dst_format == FORMAT_FRACTAL_Z_3D) {
    return TransShapeDhwckToFz3D(src_shape, data_type, dst_shape);
  }
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferDhwcnFractalZ3D, FORMAT_DHWCN, FORMAT_FRACTAL_Z_3D)
--- a/ge/common/formats/format_transfers/format_transfer_dhwnc_fracz3D_transpose.cc
+++ b/ge/common/formats/format_transfers/format_transfer_dhwnc_fracz3D_transpose.cc
@@ -32,7 +32,7 @@ Status TransShapeToFz(int64_t d, int64_t n, int64_t c, int64_t h, int64_t w, Dat
                      std::vector<int64_t> &dst_shape) {
  auto c0 = GetCubeSizeByDataType(data_type);
  if (c0 < 0) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  auto c1 = Ceil(c, c0);
@@ -50,7 +50,7 @@ Status TransShapeToFz(int64_t d, int64_t n, int64_t c, int64_t h, int64_t w, Dat
 Status TransShapeDhwncToFz3DTranspose(const std::vector<int64_t> &src_shape, DataType data_type,
                                      std::vector<int64_t> &dst_shape) {
  if (!CheckShapeValid(src_shape, kDhwncDimsNum)) {
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto d = src_shape.at(kDhwncD);
  auto h = src_shape.at(kDhwncH);
@@ -62,7 +62,7 @@ Status TransShapeDhwncToFz3DTranspose(const std::vector<int64_t> &src_shape, Dat
 }
 Status TransFormatDhwncToFz3DTranspose(const TransArgs &args, TransResult &result) {
  if (!CheckShapeValid(args.src_shape, kDhwncDimsNum)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  int64_t d = args.src_shape[kDhwncD];
  int64_t h = args.src_shape[kDhwncH];
@@ -95,10 +95,10 @@ Status TransFormatDhwncToFz3DTranspose(const TransArgs &args, TransResult &resul
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  for (int64_t di = 0; di < d; di++) {
@@ -123,9 +123,9 @@ Status TransFormatDhwncToFz3DTranspose(const TransArgs &args, TransResult &resul
                               args.data + src_idx * data_size, static_cast<size_t>(data_size));
              }
              if (ret != EOK) {
                GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
                GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
                       dst_offset, ret, pad_zero);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
              }
            }
          }
@@ -150,28 +150,28 @@ Status FormatTransferDhwncFractalZ3DTranspose::TransFormat(const TransArgs &args
    return ret;
  }
  if (!IsTransShapeDstCorrect(args, expect_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (args.src_format == ge::FORMAT_DHWNC && args.dst_format == ge::FORMAT_FRACTAL_Z_3D_TRANSPOSE) {
    return TransFormatDhwncToFz3DTranspose(args, result);
  }
  return UNSUPPORTED;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 Status FormatTransferDhwncFractalZ3DTranspose::TransShape(Format src_format, const std::vector<int64_t> &src_shape,
                                                          DataType data_type, Format dst_format,
                                                          std::vector<int64_t> &dst_shape) {
  if (CheckDataTypeSupport(data_type) != SUCCESS) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (src_format == FORMAT_DHWNC && dst_format == FORMAT_FRACTAL_Z_3D_TRANSPOSE) {
    return TransShapeDhwncToFz3DTranspose(src_shape, data_type, dst_shape);
  }
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferDhwncFractalZ3DTranspose, FORMAT_DHWNC, FORMAT_FRACTAL_Z_3D_TRANSPOSE)
--- a/ge/common/formats/format_transfers/format_transfer_fractal_nz.cc
+++ b/ge/common/formats/format_transfers/format_transfer_fractal_nz.cc
@@ -87,8 +87,8 @@ Status TransShapeToFracNz(const ShapeVector &src_shape, DataType data_type, Shap
      hw_shape.push_back(DIM_DEFAULT_VALUE);
      hw_shape.push_back(src_shape[kNdDimIndexN]);
      if (!IsShapeValid(dst_shape)) {
        GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
        return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
        GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
        return ACL_ERROR_GE_SHAPE_INVALID;
      }
      return SUCCESS;
    default:
@@ -106,8 +106,8 @@ Status TransShapeToFracNz(const ShapeVector &src_shape, DataType data_type, Shap
      hw_shape.push_back(src_shape[size - kNdDimCountBackwardsWH]);
      hw_shape.push_back(src_shape[size - kNdDimCountBackwardsW]);
      if (!IsShapeValid(dst_shape)) {
        GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
        return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
        GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
        return ACL_ERROR_GE_SHAPE_INVALID;
      }
      return SUCCESS;
  }
@@ -117,14 +117,14 @@ Status CheckShapeRelation(const TransArgs &args, ShapeVector &hw_shape) {
  ShapeVector expect_src_shape;
  auto ret = TransShapeToFracNz(args.dst_shape, args.src_data_type, expect_src_shape, hw_shape);
  if (ret != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Trans shape from %s to %s, shape %s to %s, data type %s failed",
    GELOGE(ret, "Trans shape from %s to %s, shape %s to %s, data type %s failed",
           TypeUtils::FormatToSerialString(args.dst_format).c_str(),
           TypeUtils::FormatToSerialString(args.src_format).c_str(), ShapeToString(args.dst_shape).c_str(),
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return INTERNAL_ERROR;
    return ret;
  }
  if (!IsTransShapeSrcCorrect(args, expect_src_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
 }
@@ -139,10 +139,10 @@ Status TransFormatFromNdToFracNz(const TransArgs &args, TransResult &result, con
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size](), std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  // src&dst_shape can be written as times*H*W & times*W1*H1*H0*W0, respectively. dst_shape_size >= kDimNum4D
@@ -175,8 +175,8 @@ Status TransFormatFromNdToFracNz(const TransArgs &args, TransResult &result, con
        auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                            static_cast<size_t>(size * w0));
        if (ret != EOK) {
          GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return INTERNAL_ERROR;
          GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
        }
      }
      auto w1_head = num_w1 * w0;
@@ -189,8 +189,8 @@ Status TransFormatFromNdToFracNz(const TransArgs &args, TransResult &result, con
        auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                            static_cast<size_t>(size));
        if (ret != EOK) {
          GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return INTERNAL_ERROR;
          GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
        }
      }
    }
@@ -210,10 +210,10 @@ Status TransFormatFromFracNzToNd(const TransArgs &args, TransResult &result, con
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto times = dst_hw_shape.at(kNdDimIndexN);
@@ -246,8 +246,8 @@ Status TransFormatFromFracNzToNd(const TransArgs &args, TransResult &result, con
        ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                       static_cast<size_t>(size * w0));
        if (ret != EOK) {
          GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return INTERNAL_ERROR;
          GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
        }
      }
      auto w1_head = num_w1 * w0;
@@ -260,8 +260,8 @@ Status TransFormatFromFracNzToNd(const TransArgs &args, TransResult &result, con
        ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                       static_cast<size_t>(size));
        if (ret != EOK) {
          GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return INTERNAL_ERROR;
          GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
          return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
        }
      }
    }
@@ -273,13 +273,19 @@ Status TransFormatFromFracNzToNd(const TransArgs &args, TransResult &result, con
 }  // namespace
 Status FormatTransferFractalNz::TransFormat(const TransArgs &args, TransResult &result) {
  if (!IsDataTypeSupport(args.src_data_type) || !CheckShape(args.src_format, args.src_shape) ||
      !IsShapeValid(args.dst_shape)) {
    GELOGE(PARAM_INVALID, "Trans format from %s to %s, src shape %s, dst shape %s, data type %s is not supported",
  if (!IsDataTypeSupport(args.src_data_type)) {
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Trans format from %s to %s, src shape %s, dst shape %s, data type %s is not supported",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShape(args.src_format, args.src_shape) || !IsShapeValid(args.dst_shape)) {
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Trans format from %s to %s, src shape %s, dst shape %s, data type %s is not supported",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from %s to %s, src shape %s, dst shape %s, data type %s",
         TypeUtils::FormatToSerialString(args.src_format).c_str(),
@@ -292,7 +298,7 @@ Status FormatTransferFractalNz::TransFormat(const TransArgs &args, TransResult &
    return ret;
  }
  if (!IsTransShapeDstCorrect(args, expect_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return TransFormatFromNdToFracNz(args, result, hw_shape);
 }
@@ -300,31 +306,38 @@ Status FormatTransferFractalNz::TransFormat(const TransArgs &args, TransResult &
 Status FormatTransferFractalNz::TransShape(Format src_format, const ShapeVector &src_shape, DataType data_type,
                                           Format dst_format, ShapeVector &dst_shape) {
  if (!IsDataTypeSupport(data_type)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID,
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID,
           "Trans format from %s to %s, src shape %s, data type %s is not supported",
           TypeUtils::FormatToSerialString(src_format).c_str(), TypeUtils::FormatToSerialString(dst_format).c_str(),
           ShapeToString(src_shape).c_str(), TypeUtils::DataTypeToSerialString(data_type).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShape(src_format, src_shape)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID,
           "Trans format from %s to %s, src shape %s, data type %s is not supported",
           TypeUtils::FormatToSerialString(src_format).c_str(), TypeUtils::FormatToSerialString(dst_format).c_str(),
           ShapeToString(src_shape).c_str(), TypeUtils::DataTypeToSerialString(data_type).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  ShapeVector hw_shape;
  return TransShapeToFracNz(src_shape, data_type, dst_shape, hw_shape);
 }
 Status FormatTransferFractalNzND::TransFormat(const TransArgs &args, TransResult &result) {
  if (!IsDataTypeSupport(args.src_data_type) || !IsShapeValid(args.src_shape) ||
      !CheckShape(args.dst_format, args.dst_shape)) {
    GELOGE(PARAM_INVALID, "Trans format from %s to %s, src shape %s, dst shape %s, data type %s is not supported",
  if (!IsDataTypeSupport(args.src_data_type)) {
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Trans format from %s to %s, src shape %s, dst shape %s, data type %s is not supported",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!IsShapeValid(args.src_shape) || !CheckShape(args.dst_format, args.dst_shape)) {
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Trans format from %s to %s, src shape %s, dst shape %s, data type %s is not supported",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from %s to %s, src shape %s, dst shape %s, data type %s",
         TypeUtils::FormatToSerialString(args.src_format).c_str(),
@@ -332,8 +345,9 @@ Status FormatTransferFractalNzND::TransFormat(const TransArgs &args, TransResult
         ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
  ShapeVector hw_shape;
  if (CheckShapeRelation(args, hw_shape) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckShapeRelation(args, hw_shape);
  if (ret != SUCCESS) {
    return ret;
  }
  return TransFormatFromFracNzToNd(args, result, hw_shape);
 }
@@ -342,7 +356,7 @@ Status FormatTransferFractalNzND::TransShape(Format src_format, const ShapeVecto
                                             Format dst_format, ShapeVector &dst_shape) {
  GELOGD("The shape derivation from %s to %s is not unique. Trans shape is not supported",
         TypeUtils::FormatToSerialString(src_format).c_str(), TypeUtils::FormatToSerialString(dst_format).c_str());
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferFractalNz, FORMAT_ND, FORMAT_FRACTAL_NZ)
--- a/ge/common/formats/format_transfers/format_transfer_fractal_z.cc
+++ b/ge/common/formats/format_transfers/format_transfer_fractal_z.cc
@@ -42,7 +42,7 @@ Status CheckDataTypeSupport(DataType data_type) { return GetSizeByDataType(data_
 Status TransShapeToFz(int64_t n, int64_t c, int64_t h, int64_t w, DataType data_type, std::vector<int64_t> &dst_shape) {
  auto c0 = GetCubeSizeByDataType(data_type);
  if (c0 < 0) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  auto c1 = Ceil(c, c0);
@@ -54,16 +54,16 @@ Status TransShapeToFz(int64_t n, int64_t c, int64_t h, int64_t w, DataType data_
  dst_shape.push_back(kNiSize);
  dst_shape.push_back(c0);
  if (!IsShapeValid(dst_shape)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s",
           ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
 }
 Status TransShapeNchwToFz(const std::vector<int64_t> &src_shape, DataType data_type, std::vector<int64_t> &dst_shape) {
  if (!CheckShapeValid(src_shape, kNchwDimsNum)) {
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto n = src_shape.at(kNchwN);
@@ -75,7 +75,7 @@ Status TransShapeNchwToFz(const std::vector<int64_t> &src_shape, DataType data_t
 Status TransShapeHwcnToFz(const std::vector<int64_t> &src_shape, DataType data_type, std::vector<int64_t> &dst_shape) {
  if (!CheckShapeValid(src_shape, kHwcnDimsNum)) {
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto h = src_shape.at(kHwcnH);
@@ -88,7 +88,7 @@ Status TransShapeHwcnToFz(const std::vector<int64_t> &src_shape, DataType data_t
 Status TransShapeNhwcToFz(const std::vector<int64_t> &src_shape, DataType data_type, std::vector<int64_t> &dst_shape) {
  if (!CheckShapeValid(src_shape, kNhwcDimsNum)) {
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto n = src_shape.at(kNhwcN);
@@ -127,10 +127,10 @@ Status TransFormatFromNchwToFz(const TransArgs &args, TransResult &result) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(
      dst == nullptr,
      GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
      GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
             TypeUtils::FormatToSerialString(args.src_format).c_str(),
             TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
      return OUT_OF_MEMORY;);
      return ACL_ERROR_GE_MEMORY_ALLOCATION;);
  for (int64_t vfi = 0; vfi < vf_cnt; vfi++) {
    // vertical fractal matrix base index
@@ -163,8 +163,8 @@ Status TransFormatFromNchwToFz(const TransArgs &args, TransResult &result) {
            if (protected_size < size) {
              std::string error = "Failed to operate the dst memory, protected_size is " +
                  FmtToStr(protected_size) + " and size is " + FmtToStr(size);
              GE_ERRORLOG_AND_ERRORMSG(INTERNAL_ERROR, error.c_str());
              return INTERNAL_ERROR;
              GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_PARAM_INVALID, error.c_str());
              return ACL_ERROR_GE_PARAM_INVALID;
            }
            char *dst_data = reinterpret_cast<char *>(dst.get() + offset);
            const char *src_data = reinterpret_cast<const char *>(args.data + src_offset * size);
@@ -173,9 +173,9 @@ Status TransFormatFromNchwToFz(const TransArgs &args, TransResult &result) {
            }
          }
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d pad mode %d", offset,
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d pad mode %d", offset,
                   ret, need_pad_zero);
            return INTERNAL_ERROR;
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
      }
@@ -213,10 +213,10 @@ Status TransFormatHwcnToFz(const TransArgs &args, TransResult &result) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(
      dst == nullptr,
      GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
      GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
             TypeUtils::FormatToSerialString(args.src_format).c_str(),
             TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
      return OUT_OF_MEMORY;);
      return ACL_ERROR_GE_MEMORY_ALLOCATION;);
  for (int64_t c1i = 0; c1i < c1; c1i++) {
    for (int64_t hi = 0; hi < h; hi++) {
@@ -235,9 +235,9 @@ Status TransFormatHwcnToFz(const TransArgs &args, TransResult &result) {
                             static_cast<size_t>(data_size));
            } else {
              if (protected_size < data_size) {
                GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory, protected_size is %ld and size is %ld",
                GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Failed to operate the dst memory, protected_size is %ld and size is %ld",
                       protected_size, data_size);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_PARAM_INVALID;
              }
              int64_t src_idx = hi * wcn + wi * cn + (c1i * c0 + c0i) * n + n1n0i;
              char *dst_data = reinterpret_cast<char *>(dst.get() + dst_offset);
@@ -247,9 +247,9 @@ Status TransFormatHwcnToFz(const TransArgs &args, TransResult &result) {
              }
            }
            if (ret != EOK) {
              GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
              GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
                     dst_offset, ret, pad_zero);
              return INTERNAL_ERROR;
              return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
            }
          }
        }
@@ -288,10 +288,10 @@ Status TransFormatNhwcToFz(const TransArgs &args, TransResult &result) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(
      dst == nullptr,
      GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
      GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
             TypeUtils::FormatToSerialString(args.src_format).c_str(),
             TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
      return OUT_OF_MEMORY;);
      return ACL_ERROR_GE_MEMORY_ALLOCATION;);
  for (int64_t c1i = 0; c1i < c1; c1i++) {
    for (int64_t hi = 0; hi < h; hi++) {
@@ -310,9 +310,9 @@ Status TransFormatNhwcToFz(const TransArgs &args, TransResult &result) {
                             static_cast<size_t>(data_size));
            } else {
              if (protected_size < data_size) {
                GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory, protected_size is %ld and size is %ld",
                GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Failed to operate the dst memory, protected_size is %ld and size is %ld",
                       protected_size, data_size);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_PARAM_INVALID;
              }
              int64_t src_idx = n1n0i * hwc + hi * wc + wi * c + (c1i * c0 + c0i);
              char *dst_data = reinterpret_cast<char *>(dst.get() + dst_offset);
@@ -322,9 +322,9 @@ Status TransFormatNhwcToFz(const TransArgs &args, TransResult &result) {
              }
            }
            if (ret != EOK) {
              GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
              GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d, pad mode %d",
                     dst_offset, ret, pad_zero);
              return INTERNAL_ERROR;
              return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
            }
          }
        }
@@ -349,7 +349,7 @@ Status FormatTransferFractalZ::TransFormat(const TransArgs &args, TransResult &r
    return ret;
  }
  if (!IsTransShapeDstCorrect(args, expect_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (args.src_format == FORMAT_NHWC && args.dst_format == FORMAT_FRACTAL_Z) {
@@ -364,13 +364,13 @@ Status FormatTransferFractalZ::TransFormat(const TransArgs &args, TransResult &r
    return TransFormatFromNchwToFz(args, result);
  }
  return UNSUPPORTED;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 Status FormatTransferFractalZ::TransShape(Format src_format, const std::vector<int64_t> &src_shape, DataType data_type,
                                          Format dst_format, std::vector<int64_t> &dst_shape) {
  if (CheckDataTypeSupport(data_type) != SUCCESS) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (src_format == FORMAT_NHWC && dst_format == FORMAT_FRACTAL_Z) {
@@ -383,7 +383,7 @@ Status FormatTransferFractalZ::TransShape(Format src_format, const std::vector<i
    return TransShapeNchwToFz(src_shape, data_type, dst_shape);
  }
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferFractalZ, FORMAT_NCHW, FORMAT_FRACTAL_Z)
--- a/ge/common/formats/format_transfers/format_transfer_fractal_zz.cc
+++ b/ge/common/formats/format_transfers/format_transfer_fractal_zz.cc
@@ -86,9 +86,9 @@ Status TransShapeToFracZz(const ShapeVector &src_shape, DataType data_type, Shap
      hw_shape.push_back(DIM_DEFAULT_VALUE);
      hw_shape.push_back(src_shape[kNdDimIndexN]);
      if (!IsShapeValid(dst_shape)) {
        GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s",
        GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s",
               ShapeToString(dst_shape).c_str());
        return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
        return ACL_ERROR_GE_SHAPE_INVALID;
      }
      return SUCCESS;
    default:
@@ -106,9 +106,9 @@ Status TransShapeToFracZz(const ShapeVector &src_shape, DataType data_type, Shap
      hw_shape.push_back(src_shape[size - kNdDimCountBackwardsWH]);
      hw_shape.push_back(src_shape[size - kNdDimCountBackwardsW]);
      if (!IsShapeValid(dst_shape)) {
        GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s",
        GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s",
               ShapeToString(dst_shape).c_str());
        return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
        return ACL_ERROR_GE_SHAPE_INVALID;
      }
      return SUCCESS;
  }
@@ -118,14 +118,14 @@ Status CheckShapeRelation(const TransArgs &args, ShapeVector &hw_shape) {
  ShapeVector expect_src_shape;
  auto ret = TransShapeToFracZz(args.dst_shape, args.src_data_type, expect_src_shape, hw_shape);
  if (ret != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Trans shape from %s to %s, shape %s to %s, data type %s failed",
    GELOGE(ret, "Trans shape from %s to %s, shape %s to %s, data type %s failed",
           TypeUtils::FormatToSerialString(args.dst_format).c_str(),
           TypeUtils::FormatToSerialString(args.src_format).c_str(), ShapeToString(args.dst_shape).c_str(),
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return INTERNAL_ERROR;
    return ret;
  }
  if (!IsTransShapeSrcCorrect(args, expect_src_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
 }
@@ -140,10 +140,10 @@ Status TransFormatFromNdToFracZz(const TransArgs &args, TransResult &result, con
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size](), std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  // The src&dst_shape can be written as times*H*W & times*H1*W1*H0*W0, respectively. dst_shape_size >= kDimNum4D
  auto times = hw_shape.at(kNdDimIndexN);
@@ -179,8 +179,8 @@ Status TransFormatFromNdToFracZz(const TransArgs &args, TransResult &result, con
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size * w0));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return INTERNAL_ERROR;
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
        auto w1_head = num_w1 * w0;
@@ -195,8 +195,8 @@ Status TransFormatFromNdToFracZz(const TransArgs &args, TransResult &result, con
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return INTERNAL_ERROR;
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
      }
@@ -217,10 +217,10 @@ Status TransFormatFromFracZzToNd(const TransArgs &args, TransResult &result, con
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size](), std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  // The src&dst_shape can be written as times*H*W & times*H1*W1*H0*W0, respectively. dst_shape_size >= kDimNum4D
@@ -257,8 +257,8 @@ Status TransFormatFromFracZzToNd(const TransArgs &args, TransResult &result, con
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size * w0));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return INTERNAL_ERROR;
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
        auto w1_head = num_w1 * w0;
@@ -273,8 +273,8 @@ Status TransFormatFromFracZzToNd(const TransArgs &args, TransResult &result, con
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return INTERNAL_ERROR;
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "Failed to operate the dst memory at offset %ld, error-code %d", dst_offset, ret);
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
      }
@@ -287,13 +287,19 @@ Status TransFormatFromFracZzToNd(const TransArgs &args, TransResult &result, con
 }  // namespace
 Status FormatTransferFractalZz::TransFormat(const TransArgs &args, TransResult &result) {
  if (!IsDataTypeSupport(args.src_data_type) || !CheckShape(args.src_format, args.src_shape) ||
      !IsShapeValid(args.dst_shape)) {
    GELOGE(PARAM_INVALID, "Not support trans format from %s to %s, src shape %s, dst shape %s, data type %s",
  if (!IsDataTypeSupport(args.src_data_type)) {
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Not support trans format from %s to %s, src shape %s, dst shape %s, data type %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShape(args.src_format, args.src_shape) || !IsShapeValid(args.dst_shape)) {
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Not support trans format from %s to %s, src shape %s, dst shape %s, data type %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from %s to %s, src shape %s, dst shape %s, data type %s",
         TypeUtils::FormatToSerialString(args.src_format).c_str(),
@@ -306,7 +312,7 @@ Status FormatTransferFractalZz::TransFormat(const TransArgs &args, TransResult &
    return ret;
  }
  if (!IsTransShapeDstCorrect(args, expect_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return TransFormatFromNdToFracZz(args, result, hw_shape);
 }
@@ -314,31 +320,38 @@ Status FormatTransferFractalZz::TransFormat(const TransArgs &args, TransResult &
 Status FormatTransferFractalZz::TransShape(Format src_format, const ShapeVector &src_shape, DataType data_type,
                                           Format dst_format, ShapeVector &dst_shape) {
  if (!IsDataTypeSupport(data_type)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID,
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID,
           "Not support trans format from %s to %s, src shape %s, data type %s",
           TypeUtils::FormatToSerialString(src_format).c_str(), TypeUtils::FormatToSerialString(dst_format).c_str(),
           ShapeToString(src_shape).c_str(), TypeUtils::DataTypeToSerialString(data_type).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShape(src_format, src_shape)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID,
           "Not support trans format from %s to %s, src shape %s, data type %s",
           TypeUtils::FormatToSerialString(src_format).c_str(), TypeUtils::FormatToSerialString(dst_format).c_str(),
           ShapeToString(src_shape).c_str(), TypeUtils::DataTypeToSerialString(data_type).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  ShapeVector hw_shape;
  return TransShapeToFracZz(src_shape, data_type, dst_shape, hw_shape);
 }
 Status FormatTransferFractalZzND::TransFormat(const TransArgs &args, TransResult &result) {
  if (!IsDataTypeSupport(args.src_data_type) || !IsShapeValid(args.src_shape) ||
      !CheckShape(args.dst_format, args.dst_shape)) {
    GELOGE(PARAM_INVALID, "Not support trans format from %s to %s, src shape %s, dst shape %s, data type %s",
  if (!IsDataTypeSupport(args.src_data_type)) {
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Not support trans format from %s to %s, src shape %s, dst shape %s, data type %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!IsShapeValid(args.src_shape) || !CheckShape(args.dst_format, args.dst_shape)) {
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Not support trans format from %s to %s, src shape %s, dst shape %s, data type %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from %s to %s, src shape %s, dst shape %s, data type %s",
         TypeUtils::FormatToSerialString(args.src_format).c_str(),
@@ -346,8 +359,9 @@ Status FormatTransferFractalZzND::TransFormat(const TransArgs &args, TransResult
         ShapeToString(args.dst_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
  ShapeVector hw_shape;
  if (CheckShapeRelation(args, hw_shape) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckShapeRelation(args, hw_shape);
  if (ret != SUCCESS) {
    return ret;
  }
  return TransFormatFromFracZzToNd(args, result, hw_shape);
 }
@@ -356,7 +370,7 @@ Status FormatTransferFractalZzND::TransShape(Format src_format, const ShapeVecto
                                             Format dst_format, ShapeVector &dst_shape) {
  GELOGD("The shape derivation from %s to %s is not unique. Trans shape is not supported",
         TypeUtils::FormatToSerialString(src_format).c_str(), TypeUtils::FormatToSerialString(dst_format).c_str());
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferFractalZz, FORMAT_ND, FORMAT_FRACTAL_ZZ)
--- a/ge/common/formats/format_transfers/format_transfer_fracz_hwcn.cc
+++ b/ge/common/formats/format_transfers/format_transfer_fracz_hwcn.cc
@@ -37,25 +37,25 @@ Status CheckArgsForFracZToHwcn(const TransArgs &args) {
    std::string error = "Dose not support trans format from " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  if (!CheckDataTypeSupported(args.src_data_type)) {
    GELOGE(UNSUPPORTED, "Failed to trans shape from FORMAT_FRACTAL_Z to HWCN, invalid data type %s",
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to trans shape from FORMAT_FRACTAL_Z to HWCN, invalid data type %s",
           TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return UNSUPPORTED;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShapeValid(src_shape, kFracZDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check src shape %s", ShapeToString(src_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s", ShapeToString(src_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (!CheckShapeValid(dst_shape, kHwcnDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  int64_t c0 = GetCubeSizeByDataType(args.src_data_type);
  if (c0 < 0) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  int64_t c1 = Ceil(dst_shape.at(kHwcnC), c0);
  int64_t n0 = Ceil(dst_shape.at(kHwcnN), static_cast<int64_t>(kNiSize));
@@ -64,8 +64,8 @@ Status CheckArgsForFracZToHwcn(const TransArgs &args) {
    std::string error = "Failed to check relationship between src shape" +
        FmtToStr(ShapeToString(src_shape)) + " and dst shape" +
        FmtToStr(ShapeToString(dst_shape));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return PARAM_INVALID;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_SHAPE_INVALID, error.c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  } 
  return SUCCESS;
@@ -74,10 +74,10 @@ Status CheckArgsForFracZToHwcn(const TransArgs &args) {
 Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const int size, const int64_t total_size) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), total_size, ShapeToString(args.dst_shape).c_str());
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto n0 = args.src_shape.at(kFracZN0);
@@ -113,11 +113,11 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR,
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                   "Failed to copy data from FracZ offset %ld to HWCN[%ld, %ld, %ld, %ld] "
                   "offset %ld, err-code %d",
                   src_offset, h_idx, w_idx, c_idx, n_idx, dst_offset, ret);
            return INTERNAL_ERROR;
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
      }
@@ -130,8 +130,9 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
 }  // namespace
 Status FormatTransferFracZHwcn::TransFormat(const TransArgs &args, TransResult &result) {
  if (CheckArgsForFracZToHwcn(args) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckArgsForFracZToHwcn(args);
  if (ret != SUCCESS) {
    return ret;
  }
  int size = GetSizeByDataType(args.src_data_type);
  auto total_size = GetItemNumByShape(args.dst_shape) * size;
@@ -142,18 +143,19 @@ Status FormatTransferFracZHwcn::TransFormat(const TransArgs &args, TransResult &
      return SUCCESS;
    }
    GELOGE(INTERNAL_ERROR, "Get %ld total size from dst shape %s, src shape %s", total_size,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Get %ld total size from dst shape %s, src shape %s", total_size,
        ShapeToString(args.dst_shape).c_str(), ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from FracZ to HWCN, src shape %s, data type %s, dst shape %s, memory size %ld",
         ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
         ShapeToString(args.dst_shape).c_str(), total_size);
  if (GetDstDataAfterTrans(args, result, size, total_size) != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
  ret = GetDstDataAfterTrans(args, result, size, total_size);
  if (ret != SUCCESS) {
    GELOGE(ret, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
           ShapeToString(args.dst_shape).c_str(), total_size);
    return INTERNAL_ERROR;
    return ret;
  }
  return SUCCESS;
 }
@@ -161,7 +163,7 @@ Status FormatTransferFracZHwcn::TransFormat(const TransArgs &args, TransResult &
 Status FormatTransferFracZHwcn::TransShape(Format src_format, const std::vector<int64_t> &src_shape, DataType data_type,
                                           Format dst_format, std::vector<int64_t> &dst_shape) {
  GELOGD("The shape derivation from FracZ to HWCN is not unique. Trans shape in this direction is not supported");
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferFracZHwcn, FORMAT_FRACTAL_Z, FORMAT_HWCN)
--- a/ge/common/formats/format_transfers/format_transfer_fracz_nchw.cc
+++ b/ge/common/formats/format_transfers/format_transfer_fracz_nchw.cc
@@ -38,32 +38,32 @@ Status CheckArgsForFracZToNchw(const TransArgs &args) {
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  if (!CheckDataTypeSupported(args.src_data_type)) {
    GELOGE(UNSUPPORTED, "Failed to trans shape from FORMAT_FRACTAL_Z to NCHW, invalid data type %s",
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to trans shape from FORMAT_FRACTAL_Z to NCHW, invalid data type %s",
           TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return UNSUPPORTED;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShapeValid(src_shape, kFracZDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check src shape %s", ShapeToString(src_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s", ShapeToString(src_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (!CheckShapeValid(dst_shape, kNchwDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  int64_t c0 = GetCubeSizeByDataType(args.src_data_type);
  if (c0 < 0) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  int64_t c1 = Ceil(dst_shape.at(kNchwC), c0);
  int64_t n0 = Ceil(dst_shape.at(kNchwN), static_cast<int64_t>(kNiSize));
  if (src_shape.at(kFracZHWC1) != dst_shape.at(kNchwH) * dst_shape.at(kNchwW) * c1 || src_shape.at(kFracZC0) != c0 ||
      src_shape.at(kFracZNi) != kNiSize || src_shape.at(kFracZN0) != n0) {
    GELOGE(PARAM_INVALID, "Failed to check relationship between src and dst shape, src shape %s, dst shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check relationship between src and dst shape, src shape %s, dst shape %s",
           ShapeToString(src_shape).c_str(), ShapeToString(dst_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
@@ -72,10 +72,10 @@ Status CheckArgsForFracZToNchw(const TransArgs &args) {
 Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const int size, const int64_t total_size) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), total_size, ShapeToString(args.dst_shape).c_str());
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto n0 = args.src_shape.at(kFracZN0);
@@ -111,11 +111,11 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR,
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                   "Failed to copy data from FracZ offset %ld to NCHW[%ld, %ld, %ld, %ld] offset %ld, "
                   "err-code %d",
                   src_offset, n_idx, c_idx, h_idx, w_idx, dst_offset, ret);
            return INTERNAL_ERROR;
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
      }
@@ -128,8 +128,9 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
 }  // namespace
 Status FormatTransferFracZNchw::TransFormat(const TransArgs &args, TransResult &result) {
  if (CheckArgsForFracZToNchw(args) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckArgsForFracZToNchw(args);
  if (ret != SUCCESS) {
    return ret;
  }
  int size = GetSizeByDataType(args.src_data_type);
  auto total_size = GetItemNumByShape(args.dst_shape) * size;
@@ -140,19 +141,20 @@ Status FormatTransferFracZNchw::TransFormat(const TransArgs &args, TransResult &
      return SUCCESS;
    }
    GELOGE(INTERNAL_ERROR, "Get %ld total size from dst shape %s, src shape %s", total_size,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Get %ld total size from dst shape %s, src shape %s", total_size,
        ShapeToString(args.dst_shape).c_str(), ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from FracZ to NCHW, src shape %s, data type %s, dst shape %s, memory size %ld",
         ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
         ShapeToString(args.dst_shape).c_str(), total_size);
  if (GetDstDataAfterTrans(args, result, size, total_size) != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
  ret = GetDstDataAfterTrans(args, result, size, total_size);
  if (ret != SUCCESS) {
    GELOGE(ret, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
           ShapeToString(args.dst_shape).c_str(), total_size);
    return INTERNAL_ERROR;
    return ret;
  }
  return SUCCESS;
 }
@@ -160,7 +162,7 @@ Status FormatTransferFracZNchw::TransFormat(const TransArgs &args, TransResult &
 Status FormatTransferFracZNchw::TransShape(Format src_format, const std::vector<int64_t> &src_shape, DataType data_type,
                                           Format dst_format, std::vector<int64_t> &dst_shape) {
  GELOGD("The shape derivation from FracZ to NCHW is not unique. Trans shape in this direction is not supported");
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferFracZNchw, FORMAT_FRACTAL_Z, FORMAT_NCHW)
--- a/ge/common/formats/format_transfers/format_transfer_hwcn_c1hwncoc0.cc
+++ b/ge/common/formats/format_transfers/format_transfer_hwcn_c1hwncoc0.cc
@@ -43,9 +43,9 @@ Status TransShapeHwcnToC1hwncoc0(const DataType &data_type, const std::vector<in
  dst_shape.push_back(cube_size);
  dst_shape.push_back(cube_size);
  if (!CheckShapeValid(dst_shape, kC1hwncoc0DimsNum)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s",
           ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
 }
@@ -55,21 +55,21 @@ Status CheckArgsForHwcnToC1hwncoc0(const TransArgs &args) {
    std::string error = "Dose not support trans format from " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  if (!CheckDataTypeSupported(args.src_data_type)) {
    GELOGE(UNSUPPORTED, "Failed to trans shape from HWCN to C1HWNCoC0, invalid data type %s",
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to trans shape from HWCN to C1HWNCoC0, invalid data type %s",
           TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return UNSUPPORTED;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShapeValid(args.src_shape, kHwcnDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check src shape %s", ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s", ShapeToString(args.src_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (!CheckShapeValid(args.dst_shape, kC1hwncoc0DimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check dst shape %s", ShapeToString(args.dst_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(args.dst_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  std::vector<int64_t> expect_dst_shape;
  auto ret = TransShapeHwcnToC1hwncoc0(args.src_data_type, args.src_shape, expect_dst_shape);
@@ -77,12 +77,12 @@ Status CheckArgsForHwcnToC1hwncoc0(const TransArgs &args) {
    return ret;
  }
  if (args.dst_shape != expect_dst_shape) {
    GELOGE(PARAM_INVALID,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID,
           "Failed to trans format, src and dst shape are not compatible. src shape %s, dst shape %s, "
           "expect dst shape %s",
           ShapeToString(args.src_shape).c_str(), ShapeToString(args.dst_shape).c_str(),
           ShapeToString(expect_dst_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
@@ -91,10 +91,10 @@ Status CheckArgsForHwcnToC1hwncoc0(const TransArgs &args) {
 Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const int size, const int64_t total_size) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), total_size, ShapeToString(args.dst_shape).c_str());
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto h = args.src_shape.at(kHwcnH);
@@ -135,22 +135,22 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
                auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                                    static_cast<size_t>(size));
                if (ret != EOK) {
                  GELOGE(INTERNAL_ERROR,
                  GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                         "Failed to copy data from HWCN[%ld, %ld, %ld, %ld] offset %ld to "
                         "C1HWNCoC0[%ld, %ld, %ld, %ld, %ld, %ld] offset %ld, err-code %d",
                         h_idx, w_idx, c_idx, n_idx, src_offset, c1_idx, h_idx, w_idx, n_idx, co_idx, c0_idx,
                         dst_offset, ret);
                  return INTERNAL_ERROR;
                  return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
                }
              } else {
                auto ret =
                    memset_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), 0, static_cast<size_t>(size));
                if (ret != EOK) {
                  GELOGE(INTERNAL_ERROR,
                  GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                         "Failed to set to 0 to C1HWNCoC0[%ld, %ld, %ld, %ld, %ld, %ld] offset %ld, "
                         "err-code %d",
                         c1_idx, h_idx, w_idx, n_idx, co_idx, c0_idx, dst_offset, ret);
                  return INTERNAL_ERROR;
                  return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
                }
              }
            }
@@ -166,8 +166,9 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
 }  // namespace
 Status FormatTransferHwcnC1hwncoc0::TransFormat(const TransArgs &args, TransResult &result) {
  if (CheckArgsForHwcnToC1hwncoc0(args) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckArgsForHwcnToC1hwncoc0(args);
  if (ret != SUCCESS) {
    return ret;
  }
  int size = GetSizeByDataType(args.src_data_type);
  auto total_size = GetItemNumByShape(args.dst_shape) * size;
@@ -178,18 +179,20 @@ Status FormatTransferHwcnC1hwncoc0::TransFormat(const TransArgs &args, TransResu
      return SUCCESS;
    }
    GELOGE(INTERNAL_ERROR, "Get %ld total size from dst shape %s, src shape %s", total_size,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Get %ld total size from dst shape %s, src shape %s", total_size,
           ShapeToString(args.dst_shape).c_str(), ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from HWCN to C1HWNCoC0, src shape %s, data type %s, dst shape %s, memory size %ld",
         ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
         ShapeToString(args.dst_shape).c_str(), total_size);
  if (GetDstDataAfterTrans(args, result, size, total_size) != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
  ret = GetDstDataAfterTrans(args, result, size, total_size);
  if (ret != SUCCESS) {
    GELOGE(ret, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
           ShapeToString(args.dst_shape).c_str(), total_size);
    return INTERNAL_ERROR;
    return ret;
  }
  return SUCCESS;
 }
@@ -198,15 +201,15 @@ Status FormatTransferHwcnC1hwncoc0::TransShape(Format src_format, const std::vec
                                               DataType data_type, Format dst_format, std::vector<int64_t> &dst_shape) {
  if (src_format == FORMAT_HWCN && CheckDataTypeSupported(data_type)) {
    if (!CheckShapeValid(src_shape, kHwcnDimsNum)) {
      GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check src shape %s",
      GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s",
             ShapeToString(src_shape).c_str());
      return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
      return ACL_ERROR_GE_SHAPE_INVALID;
    }
    return TransShapeHwcnToC1hwncoc0(data_type, src_shape, dst_shape);
  } else if (src_format != FORMAT_HWCN) {
    return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
    return ACL_ERROR_GE_FORMAT_INVALID;
  } else {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
 }
--- a/ge/common/formats/format_transfers/format_transfer_nc1hwc0_nhwc.cc
+++ b/ge/common/formats/format_transfers/format_transfer_nc1hwc0_nhwc.cc
@@ -37,33 +37,33 @@ Status CheckArgsForNc1hwc0ToNhwc(const TransArgs &args) {
    std::string error = "Dose not support trans format from " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  if (!CheckDataTypeSupported(args.src_data_type)) {
    GELOGE(UNSUPPORTED, "Failed to trans shape from NC1HWC0 to NHWC, invalid data type %s",
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to trans shape from NC1HWC0 to NHWC, invalid data type %s",
           TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return UNSUPPORTED;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShapeValid(args.src_shape, kNc1hwc0DimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check src shape %s", ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s", ShapeToString(args.src_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (!CheckShapeValid(args.dst_shape, kNhwcDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check dst shape %s", ShapeToString(args.dst_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(args.dst_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  int64_t c0 = GetCubeSizeByDataType(args.src_data_type);
  if (c0 <= 0) {
    GELOGE(PARAM_INVALID, "Failed to get cube size, the data type is invalid");
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to get cube size, the data type is invalid");
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (src_shape.at(kNc1hwc0H) != dst_shape.at(kNhwcH) || src_shape.at(kNc1hwc0W) != dst_shape.at(kNhwcW) ||
      src_shape.at(kNc1hwc0N) != dst_shape.at(kNhwcN) || src_shape.at(kNc1hwc0C0) != c0 ||
      src_shape.at(kNc1hwc0C1) != (Ceil(dst_shape.at(kNhwcC), c0))) {
    GELOGE(PARAM_INVALID, "Failed to check relationship between src and dst shape, src shape %s, dst shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check relationship between src and dst shape, src shape %s, dst shape %s",
           ShapeToString(src_shape).c_str(), ShapeToString(dst_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
@@ -72,10 +72,10 @@ Status CheckArgsForNc1hwc0ToNhwc(const TransArgs &args) {
 Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const int size, const int64_t total_size) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), total_size, ShapeToString(args.dst_shape).c_str());
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto h = args.src_shape.at(kNc1hwc0H);
@@ -109,11 +109,11 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
          auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                              static_cast<size_t>(size));
          if (ret != EOK) {
            GELOGE(INTERNAL_ERROR,
            GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                   "Failed to copy data from NC1HWC0[%ld, %ld, %ld, %ld, %ld] offset %ld to NHWC[%ld, %ld, %ld, %ld]"
                   " offset %ld, err-code %d",
                   n_idx, c1_idx, h_idx, w_idx, c0_idx, src_offset, n_idx, c_idx, h_idx, w_idx, dst_offset, ret);
            return INTERNAL_ERROR;
            return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
          }
        }
      }
@@ -126,8 +126,9 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
 }  // namespace
 Status FormatTransferNc1hwc0Nhwc::TransFormat(const TransArgs &args, TransResult &result) {
  if (CheckArgsForNc1hwc0ToNhwc(args) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckArgsForNc1hwc0ToNhwc(args);
  if (ret != SUCCESS) {
    return ret;
  }
  int size = GetSizeByDataType(args.src_data_type);
  auto total_size = GetItemNumByShape(args.dst_shape) * size;
@@ -138,18 +139,20 @@ Status FormatTransferNc1hwc0Nhwc::TransFormat(const TransArgs &args, TransResult
      return SUCCESS;
    }
    GELOGE(INTERNAL_ERROR, "Get %ld total size from dst shape %s, src shape %s", total_size,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Get %ld total size from dst shape %s, src shape %s", total_size,
           ShapeToString(args.dst_shape).c_str(), ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD("Begin to trans format from NC1HWC0 to NCHW, src shape %s, data type %s, dst shape %s, memory size %ld",
         ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
         ShapeToString(args.dst_shape).c_str(), total_size);
  if (GetDstDataAfterTrans(args, result, size, total_size) != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
  ret = GetDstDataAfterTrans(args, result, size, total_size);
  if (ret != SUCCESS) {
    GELOGE(ret, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
           ShapeToString(args.dst_shape).c_str(), total_size);
    return INTERNAL_ERROR;
    return ret;
  }
  return SUCCESS;
 }
@@ -157,7 +160,7 @@ Status FormatTransferNc1hwc0Nhwc::TransFormat(const TransArgs &args, TransResult
 Status FormatTransferNc1hwc0Nhwc::TransShape(Format src_format, const std::vector<int64_t> &src_shape,
                                             DataType data_type, Format dst_format, std::vector<int64_t> &dst_shape) {
  GELOGD("The shape derivation from NC1HWC0 to NHWC is not unique. Trans shape in this direction is not supported");
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferNc1hwc0Nhwc, FORMAT_NC1HWC0, FORMAT_NHWC)
--- a/ge/common/formats/format_transfers/format_transfer_nchw_fz_c04.cc
+++ b/ge/common/formats/format_transfers/format_transfer_nchw_fz_c04.cc
@@ -45,7 +45,7 @@ Status CheckDataTypeSupport(DataType data_type) { return GetSizeByDataType(data_
 Status TransShape(int64_t n, int64_t c, int64_t h, int64_t w, DataType data_type, std::vector<int64_t> &dst_shape) {
  auto c0 = GetCubeSizeByDataType(data_type);
  if (c0 < 0) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  auto chw = c * h * w;
@@ -59,9 +59,9 @@ Status TransShape(int64_t n, int64_t c, int64_t h, int64_t w, DataType data_type
  dst_shape.push_back(c0);
  if (!IsShapeValid(dst_shape)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s",
           ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
 }
@@ -69,7 +69,7 @@ Status TransShape(int64_t n, int64_t c, int64_t h, int64_t w, DataType data_type
 Status TransShapeNchwToFzC04(const std::vector<int64_t> &src_shape, DataType data_type,
                             std::vector<int64_t> &dst_shape) {
  if (!CheckShapeValid(src_shape, kNchwDimsNum)) {
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto n = src_shape.at(kNchwN);
@@ -94,8 +94,8 @@ Status TransFormatFromNchwToFzC04(const TransArgs &args, TransResult &result) {
  std::vector<int64_t> expect_shape = {n, h, w, c};
  auto ret = ge::formats::Transpose(data, args.src_shape, args.src_data_type, perm_arg_1, trans_result_1);
  if (ret != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to Transpose from NCHW to HWCN");
    return NOT_CHANGED;
    GELOGE(ret, "Failed to Transpose from NCHW to HWCN");
    return ret;
  }
  TransArgs args_tmp = args;
@@ -104,8 +104,8 @@ Status TransFormatFromNchwToFzC04(const TransArgs &args, TransResult &result) {
  // check size it should be same with original
  size_t expect_size = n * c * h * w * size;  // before has do check about mul
  if (trans_result_1.length != expect_size) {
    GELOGE(INTERNAL_ERROR, "size is not match after transpose!");
    return NOT_CHANGED;
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "size is not match after transpose!");
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  // prepare for padding in chw
@@ -118,20 +118,20 @@ Status TransFormatFromNchwToFzC04(const TransArgs &args, TransResult &result) {
  // data overflow check totally
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(h_o, w_o),
                  GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", h_o, w_o);
                  return INTERNAL_ERROR);
                  GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", h_o, w_o);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(n_o, c_o),
                  GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", n_o, c_o);
                  return INTERNAL_ERROR);
                  GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", n_o, c_o);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  auto t1 = h_o * w_o;
  auto t2 = n_o * c_o;
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(t1, t2), GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", t1, t2);
                  return INTERNAL_ERROR);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  int64_t total_ele_cnt = n_o * c_o * h_o * w_o;
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(total_ele_cnt, size),
                  GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%d]", total_ele_cnt, size);
                  return INTERNAL_ERROR);
                  GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%d]", total_ele_cnt, size);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  int64_t dst_size = total_ele_cnt * size;
  if (dst_size == 0) {
    result.length = 0;
@@ -140,15 +140,15 @@ Status TransFormatFromNchwToFzC04(const TransArgs &args, TransResult &result) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto retMem = memset_s(dst.get(), dst_size, 0, dst_size);
  if (retMem != EOK) {
    GELOGE(INTERNAL_ERROR, "memst failed!");
    return INTERNAL_ERROR;
    GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "memst failed!");
    return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
  }
  // copy data
  auto block = c * h * w * size;
@@ -159,8 +159,8 @@ Status TransFormatFromNchwToFzC04(const TransArgs &args, TransResult &result) {
  for (auto k = 0; k < n; k++) {
    ret = memcpy_s(p_d + k * stride, protectSize, p_s + k * block, block);
    if (ret != EOK) {
      GELOGE(INTERNAL_ERROR, "memcpy_s failed!");
      return INTERNAL_ERROR;
      GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "memcpy_s failed!");
      return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
    }
    protectSize = protectSize - block;
  }
@@ -169,8 +169,8 @@ Status TransFormatFromNchwToFzC04(const TransArgs &args, TransResult &result) {
  std::vector<int64_t> perm_arg_2 = {2, 0, 1, 3};
  ret = ge::formats::Transpose(dst.get(), shape_o, args.src_data_type, perm_arg_2, result);
  if (ret != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to Transpose from NCHW to HWCN");
    return NOT_CHANGED;
    GELOGE(ret, "Failed to Transpose from NCHW to HWCN");
    return ret;
  }
  return SUCCESS;
@@ -180,7 +180,7 @@ Status PaddingNC(const TransArgs &args, TransArgs &args_tmp, std::shared_ptr<uin
  args_tmp = args;
  auto src_shape = args_tmp.src_shape;
  if (!CheckShapeValid(src_shape, kNchwDimsNum)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  int64_t c0 = GetCubeSizeByDataType(args.src_data_type);
@@ -190,8 +190,8 @@ Status PaddingNC(const TransArgs &args, TransArgs &args_tmp, std::shared_ptr<uin
  auto w = src_shape.at(kNchwW);
  if (c > kMaxDimsNumC) {
    GELOGE(PARAM_INVALID, "Invalie dim c num[%lu].It should be in (0,4]", c);
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Invalie dim c num[%lu].It should be in (0,4]", c);
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  auto n_o = Ceil(n, c0) * c0;
@@ -205,21 +205,21 @@ Status PaddingNC(const TransArgs &args, TransArgs &args_tmp, std::shared_ptr<uin
  // data overflow check
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(h_o, w_o),
                  GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", h_o, w_o);
                  return INTERNAL_ERROR);
                  GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", h_o, w_o);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(n_o, c_o),
                  GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", n_o, c_o);
                  return INTERNAL_ERROR);
                  GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", n_o, c_o);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  auto t1 = h_o * w_o;
  auto t2 = n_o * c_o;
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(t1, t2), GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", t1, t2);
                  return INTERNAL_ERROR);
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(t1, t2), GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%ld]", t1, t2);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  int64_t total_ele_cnt = n_o * c_o * h_o * w_o;
  int size = GetSizeByDataType(args.src_data_type);
  GE_IF_BOOL_EXEC(!CheckInt64MulOverflow(total_ele_cnt, size),
                  GELOGE(INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%d]", total_ele_cnt, size);
                  return INTERNAL_ERROR);
                  GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "int64 mul overflow.A[%ld], B[%d]", total_ele_cnt, size);
                  return ACL_ERROR_GE_INTERNAL_ERROR);
  int64_t dst_size = total_ele_cnt * size;
  if (dst_size == 0) {
@@ -228,15 +228,15 @@ Status PaddingNC(const TransArgs &args, TransArgs &args_tmp, std::shared_ptr<uin
  dst.reset(new (std::nothrow) uint8_t[dst_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), dst_size);
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto ret = memset_s(dst.get(), dst_size, 0, dst_size);
  if (ret != EOK) {
    GELOGE(INTERNAL_ERROR, "memst failed!");
    return INTERNAL_ERROR;
    GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "memst failed!");
    return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
  }
  auto p_s = args.data;
@@ -249,8 +249,8 @@ Status PaddingNC(const TransArgs &args, TransArgs &args_tmp, std::shared_ptr<uin
      ret = memcpy_s(p_d + (i * c_o * h_o * w_o + j * h_o * w_o) * size, protectSize,
                     p_s + (i * c * h * w + j * h * w) * size, block);
      if (ret != EOK) {
        GELOGE(INTERNAL_ERROR, "memcpy_s failed!");
        return INTERNAL_ERROR;
        GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED, "memcpy_s failed!");
        return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
      }
      protectSize = protectSize - block;
    }
@@ -270,7 +270,7 @@ Status FormatTransferNchwToFZC04::TransFormat(const TransArgs &args, TransResult
  std::shared_ptr<uint8_t> dst = nullptr;
  auto ret = PaddingNC(args, args_tmp, dst);
  if (ret != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Padding in NC axis failed!");
    GELOGE(ret, "Padding in NC axis failed!");
    return ret;
  }
@@ -281,26 +281,26 @@ Status FormatTransferNchwToFZC04::TransFormat(const TransArgs &args, TransResult
  }
  if (!IsTransShapeDstCorrect(args_tmp, expect_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (args_tmp.src_format == FORMAT_NCHW && args_tmp.dst_format == FORMAT_FRACTAL_Z_C04) {
    return TransFormatFromNchwToFzC04(args_tmp, result);
  }
  return UNSUPPORTED;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 Status FormatTransferNchwToFZC04::TransShape(Format src_format, const std::vector<int64_t> &src_shape,
                                             DataType data_type, Format dst_format, std::vector<int64_t> &dst_shape) {
  if (CheckDataTypeSupport(data_type) != SUCCESS) {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (src_format == FORMAT_NCHW && dst_format == FORMAT_FRACTAL_Z_C04) {
    return TransShapeNchwToFzC04(src_shape, data_type, dst_shape);
  }
  return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
  return ACL_ERROR_GE_FORMAT_INVALID;
 }
 REGISTER_FORMAT_TRANSFER(FormatTransferNchwToFZC04, FORMAT_NCHW, FORMAT_FRACTAL_Z_C04)
--- a/ge/common/formats/format_transfers/format_transfer_nchw_nc1hwc0.cc
+++ b/ge/common/formats/format_transfers/format_transfer_nchw_nc1hwc0.cc
@@ -32,13 +32,13 @@ Status TransShapeNchwToNc1hwc0(const std::vector<int64_t> &src_shape, DataType d
                               std::vector<int64_t> &dst_shape) {
  int64_t c0 = GetCubeSizeByDataType(data_type);
  if (c0 <= 0) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID, "Failed to get cube size, the data type is invalid");
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to get cube size, the data type is invalid");
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShapeValid(src_shape, kNchwDimsNum)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check src shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s",
           ShapeToString(src_shape).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  dst_shape.clear();
  dst_shape.push_back(src_shape.at(kNchwN));
@@ -47,9 +47,9 @@ Status TransShapeNchwToNc1hwc0(const std::vector<int64_t> &src_shape, DataType d
  dst_shape.push_back(src_shape.at(kNchwW));
  dst_shape.push_back(c0);
  if (!CheckShapeValid(dst_shape, kNc1hwc0DimsNum)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s",
           ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
 }
@@ -59,8 +59,8 @@ Status CheckArgsForNchwToNc1hwc0(const TransArgs &args) {
    std::string error = "Dose not support trans format from " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  std::vector<int64_t> expect_5d_shape;
  auto ret = TransShapeNchwToNc1hwc0(args.src_shape, args.src_data_type, expect_5d_shape);
@@ -68,12 +68,12 @@ Status CheckArgsForNchwToNc1hwc0(const TransArgs &args) {
    return ret;
  }
  if (expect_5d_shape != args.dst_shape) {
    GELOGE(PARAM_INVALID,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID,
           "Failed to trans format, the src and dst shape are not compatible. data"
           " type %s, src shape %s, dst shape %s, expect dst shape %s",
           TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(), ShapeToString(args.src_shape).c_str(),
           ShapeToString(args.dst_shape).c_str(), ShapeToString(expect_5d_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
@@ -82,12 +82,12 @@ Status CheckArgsForNchwToNc1hwc0(const TransArgs &args) {
 Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const int size, const int64_t total_size) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY,
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION,
           "Failed to trans format from %s to %s, can not alloc the memory for"
           " dst buf %ld, shape %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), total_size, ShapeToString(args.dst_shape).c_str());
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto n = args.src_shape.at(kNchwN);
@@ -97,8 +97,8 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
  int64_t c0 = GetCubeSizeByDataType(args.src_data_type);
  if (c0 <= 0) {
    GELOGE(INTERNAL_ERROR, "The c0 is invalid %ld", c0);
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "The c0 is invalid %ld", c0);
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  int64_t c1 = (c - 1) / c0 + 1;
  int64_t hw = h * w;
@@ -129,21 +129,21 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
              auto ret = memcpy_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), args.data + src_offset,
                                  static_cast<size_t>(size));
              if (ret != EOK) {
                GELOGE(INTERNAL_ERROR,
                GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                       "Failed to copy data from NCHW[%ld] offset %ld to "
                       "NC1HWC0[%ld, %ld, %ld, %ld, %ld] offset %ld, err-code %d",
                       srcIdx, src_offset, n_idx, c1_idx, h_idx, w_idx, c0_idx, dst_offset, ret);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
              }
            } else {
              auto ret =
                  memset_s(dst.get() + dst_offset, static_cast<size_t>(protected_size), 0, static_cast<size_t>(size));
              if (ret != EOK) {
                GELOGE(INTERNAL_ERROR,
                GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                       "Failed to set to 0 to "
                       "NC1HWC0[%ld, %ld, %ld, %ld, %ld] offset %ld, err-code %d",
                       n_idx, c1_idx, h_idx, w_idx, c0_idx, dst_offset, ret);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
              }
            }
          }
@@ -159,8 +159,9 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
 }  // namespace
 Status FormatTransferNchwNc1hwc0::TransFormat(const TransArgs &args, TransResult &result) {
  if (CheckArgsForNchwToNc1hwc0(args) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckArgsForNchwToNc1hwc0(args);
  if (ret != SUCCESS) {
    return ret;
  }
  // Guarantee the validity of parameters in check function
  int size = GetSizeByDataType(args.src_data_type);
@@ -172,20 +173,21 @@ Status FormatTransferNchwNc1hwc0::TransFormat(const TransArgs &args, TransResult
      return SUCCESS;
    }
    GELOGE(INTERNAL_ERROR, "Get %ld total size from dst shape %s, src shape %s", total_size,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Get %ld total size from dst shape %s, src shape %s", total_size,
           ShapeToString(args.dst_shape).c_str(), ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  GELOGD(
      "Begin to trans format from NCHW to NC1HWC0, src shape %s, data type "
      "%s, dst shape %s memory size %ld",
      ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
      ShapeToString(args.dst_shape).c_str(), total_size);
  if (GetDstDataAfterTrans(args, result, size, total_size) != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
  ret = GetDstDataAfterTrans(args, result, size, total_size);
  if (ret != SUCCESS) {
    GELOGE(ret, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
           ShapeToString(args.dst_shape).c_str(), total_size);
    return INTERNAL_ERROR;
    return ret;
  }
  return SUCCESS;
 }
@@ -195,7 +197,7 @@ Status FormatTransferNchwNc1hwc0::TransShape(Format src_format, const std::vecto
  if (src_format == FORMAT_NCHW) {
    return TransShapeNchwToNc1hwc0(src_shape, data_type, dst_shape);
  } else {
    return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
 }
--- a/ge/common/formats/format_transfers/format_transfer_nhwc_nc1hwc0.cc
+++ b/ge/common/formats/format_transfers/format_transfer_nhwc_nc1hwc0.cc
@@ -34,8 +34,8 @@ Status TransShapeNhwcToNc1hwc0(const std::vector<int64_t> &src_shape, DataType d
                               std::vector<int64_t> &dst_shape) {
  int64_t c0 = GetCubeSizeByDataType(data_type);
  if (c0 <= 0) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID, "Failed to get cube size, the data type is invalid");
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to get cube size, the data type is invalid");
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  dst_shape.clear();
  dst_shape.push_back(src_shape.at(kNhwcN));
@@ -44,9 +44,9 @@ Status TransShapeNhwcToNc1hwc0(const std::vector<int64_t> &src_shape, DataType d
  dst_shape.push_back(src_shape.at(kNhwcW));
  dst_shape.push_back(c0);
  if (!CheckShapeValid(dst_shape, kNc1hwc0DimsNum)) {
    GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check dst shape %s",
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s",
           ShapeToString(dst_shape).c_str());
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
 }
@@ -56,21 +56,21 @@ Status CheckArgsForNhwcToNc1hwc0(const TransArgs &args) {
    std::string error = "Dose not support trans format from " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  if (!CheckDataTypeSupported(args.src_data_type)) {
    GELOGE(UNSUPPORTED, "Failed to trans shape from NHWC to NC1HWC0, invalid data type %s",
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Failed to trans shape from NHWC to NC1HWC0, invalid data type %s",
           TypeUtils::DataTypeToSerialString(args.src_data_type).c_str());
    return UNSUPPORTED;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (!CheckShapeValid(args.src_shape, kNhwcDimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check src shape %s", ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s", ShapeToString(args.src_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  if (!CheckShapeValid(args.dst_shape, kNc1hwc0DimsNum)) {
    GELOGE(PARAM_INVALID, "Failed to check dst shape %s", ShapeToString(args.dst_shape).c_str());
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check dst shape %s", ShapeToString(args.dst_shape).c_str());
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  std::vector<int64_t> expect_dst_shape;
  auto ret = TransShapeNhwcToNc1hwc0(args.src_shape, args.src_data_type, expect_dst_shape);
@@ -78,12 +78,12 @@ Status CheckArgsForNhwcToNc1hwc0(const TransArgs &args) {
    return ret;
  }
  if (args.dst_shape != expect_dst_shape) {
    GELOGE(PARAM_INVALID,
    GELOGE(ACL_ERROR_GE_SHAPE_INVALID,
           "Failed to trans format, the src and dst shape are not compatible. src shape %s, dst shape %s, "
           "expect dst shape %s",
           ShapeToString(args.src_shape).c_str(), ShapeToString(args.dst_shape).c_str(),
           ShapeToString(expect_dst_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return SUCCESS;
@@ -92,10 +92,10 @@ Status CheckArgsForNhwcToNc1hwc0(const TransArgs &args) {
 Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const int size, const int64_t total_size) {
  std::shared_ptr<uint8_t> dst(new (std::nothrow) uint8_t[total_size], std::default_delete<uint8_t[]>());
  if (dst == nullptr) {
    GELOGE(OUT_OF_MEMORY, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
    GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Failed to trans format from %s to %s, can not alloc the memory for dst buf %ld, shape %s",
           TypeUtils::FormatToSerialString(args.src_format).c_str(),
           TypeUtils::FormatToSerialString(args.dst_format).c_str(), total_size, ShapeToString(args.dst_shape).c_str());
    return OUT_OF_MEMORY;
    return ACL_ERROR_GE_MEMORY_ALLOCATION;
  }
  auto n = args.src_shape.at(kNhwcN);
@@ -131,19 +131,19 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
            if (c_idx < c) {
              auto ret = memcpy_s(dst.get() + dst_offset, protected_size, args.data + src_offset, size);
              if (ret != EOK) {
                GELOGE(INTERNAL_ERROR,
                GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                       "Failed to copy data from NHWC[%ld, %ld, %ld, %ld] offset %ld to "
                       "NC1HWC0[%ld, %ld, %ld, %ld, %ld] offset %ld err-code %d",
                       n_idx, h_idx, w_idx, c_idx, src_offset, n_idx, c1_idx, h_idx, w_idx, c0_idx, dst_offset, ret);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
              }
            } else {
              auto ret = memset_s(dst.get() + dst_offset, protected_size, 0, size);
              if (ret != EOK) {
                GELOGE(INTERNAL_ERROR,
                GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
                       "Failed to set 0 to NC1HWC0[%ld, %ld, %ld, %ld, %ld] offset %ld base err-code %d", n_idx, c1_idx,
                       h_idx, w_idx, c0_idx, dst_offset, ret);
                return INTERNAL_ERROR;
                return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
              }
            }
          }
@@ -158,8 +158,9 @@ Status GetDstDataAfterTrans(const TransArgs &args, TransResult &result, const in
 }  // namespace
 Status FormatTransferNhwcNc1hwc0::TransFormat(const TransArgs &args, TransResult &result) {
  if (CheckArgsForNhwcToNc1hwc0(args) != SUCCESS) {
    return PARAM_INVALID;
  Status ret = CheckArgsForNhwcToNc1hwc0(args);
  if (ret != SUCCESS) {
    return ret;
  }
  int size = GetSizeByDataType(args.src_data_type);
  auto total_size = GetItemNumByShape(args.dst_shape) * size;
@@ -170,18 +171,20 @@ Status FormatTransferNhwcNc1hwc0::TransFormat(const TransArgs &args, TransResult
      return SUCCESS;
    }
    GELOGE(INTERNAL_ERROR, "Get %ld total size from dst shape %s, src shape %s", total_size,
    GELOGE(ACL_ERROR_GE_DATATYPE_INVALID, "Get %ld total size from dst shape %s, src shape %s", total_size,
           ShapeToString(args.dst_shape).c_str(), ShapeToString(args.src_shape).c_str());
    return PARAM_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  GELOGD("Begin to trans format from NHWC to NC1HWC0, src shape %s, data type %s, dst shape %s, memory size %ld",
         ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
         ShapeToString(args.dst_shape).c_str(), total_size);
  if (GetDstDataAfterTrans(args, result, size, total_size) != SUCCESS) {
    GELOGE(INTERNAL_ERROR, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
  ret = GetDstDataAfterTrans(args, result, size, total_size);
  if (ret != SUCCESS) {
    GELOGE(ret, "Failed to get data after trans, src shape %s, data type %s, dst shape %s, memory size %ld",
           ShapeToString(args.src_shape).c_str(), TypeUtils::DataTypeToSerialString(args.src_data_type).c_str(),
           ShapeToString(args.dst_shape).c_str(), total_size);
    return INTERNAL_ERROR;
    return ret;
  }
  return SUCCESS;
 }
@@ -190,15 +193,15 @@ Status FormatTransferNhwcNc1hwc0::TransShape(Format src_format, const std::vecto
                                             DataType data_type, Format dst_format, std::vector<int64_t> &dst_shape) {
  if (src_format == FORMAT_NHWC && CheckDataTypeSupported(data_type)) {
    if (!CheckShapeValid(src_shape, kNhwcDimsNum)) {
      GELOGE(ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID, "Failed to check src shape %s",
      GELOGE(ACL_ERROR_GE_SHAPE_INVALID, "Failed to check src shape %s",
             ShapeToString(src_shape).c_str());
      return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
      return ACL_ERROR_GE_SHAPE_INVALID;
    }
    return TransShapeNhwcToNc1hwc0(src_shape, data_type, dst_shape);
  } else if (src_format != FORMAT_NHWC) {
    return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
    return ACL_ERROR_GE_FORMAT_INVALID;
  } else {
    return ACL_ERROR_GE_TRANSSHAPE_DATATYPE_INVALID;
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
 }
--- a/ge/common/formats/format_transfers/format_transfer_transpose.cc
+++ b/ge/common/formats/format_transfers/format_transfer_transpose.cc
@@ -141,7 +141,7 @@ std::vector<int64_t> TransShapeByPerm(const std::vector<int64_t> &src_shape, con
 Status Transpose(const uint8_t *src, const std::vector<int64_t> &src_shape, DataType src_data_type,
                 const std::vector<int64_t> &perm_arg, TransResult &result) {
  if (!IsTransposeArgValid(src, src_shape, src_data_type, perm_arg)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  auto dst_shape = TransShapeByPerm(src_shape, perm_arg);
@@ -172,12 +172,12 @@ Status Transpose(const uint8_t *src, const std::vector<int64_t> &src_shape, Data
    auto ret = memcpy_s(dst.get() + dst_offset_bytes, static_cast<size_t>(protected_size), src + src_offset,
                        static_cast<size_t>(data_size));
    if (ret != EOK) {
      GELOGE(INTERNAL_ERROR,
      GELOGE(ACL_ERROR_GE_MEMORY_OPERATE_FAILED,
             "Failed to transpose, src shape %s, perm arg %s, dst shape %s, "
             "failed to write to dst offset %ld, current dim offset %s",
             ShapeToString(src_shape).c_str(), ShapeToString(perm_arg).c_str(), ShapeToString(dst_shape).c_str(),
             dst_offset_bytes, ShapeToString(dst_indexes).c_str());
      return INTERNAL_ERROR;
      return ACL_ERROR_GE_MEMORY_OPERATE_FAILED;
    }
    AddOne(dst_shape, dst_indexes);
    ++dst_index;
@@ -192,14 +192,14 @@ Status TransposeWithShapeCheck(const uint8_t *data, const std::vector<int64_t> &
                               const std::vector<int64_t> &dst_shape, DataType src_data_type,
                               const std::vector<int64_t> &perm_arg, TransResult &result) {
  if (!IsTransposeArgValid(data, src_shape, src_data_type, perm_arg)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  auto expected_shape = TransShapeByPerm(src_shape, perm_arg);
  if (dst_shape != expected_shape) {
    std::string error = "Failed to trans axis for perm_arg" +
        FmtToStr(ShapeToString(perm_arg)) + ", invalid dst shape" +
        FmtToStr(ShapeToString(dst_shape)) + ", expect" + FmtToStr(ShapeToString(expected_shape));
    GE_ERRORLOG_AND_ERRORMSG(PARAM_INVALID, error.c_str());
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_SHAPE_INVALID, error.c_str());
  }
  return Transpose(data, src_shape, src_data_type, perm_arg, result);
@@ -211,16 +211,16 @@ Status GetPermByForamt(Format src_format, Format dst_format, std::vector<int64_t
    std::string error = "Failed to trans shape, do not support transpose from format " +
        FmtToStr(TypeUtils::FormatToSerialString(src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(dst_format));
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  auto iter = dst_iter->second.find(dst_format);
  if (iter == dst_iter->second.end()) {
    std::string error = "Failed to trans shape, do not support transpose from format " +
        FmtToStr(TypeUtils::FormatToSerialString(src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(dst_format));
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  perm = iter->second;
  return SUCCESS;
@@ -233,7 +233,7 @@ Status FormatTransferTranspose::TransFormat(const TransArgs &args, TransResult &
    return ret;
  }
  if (!IsTransShapeDstCorrect(args, expected_shape)) {
    return PARAM_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  return Transpose(args.data, args.src_shape, args.src_data_type, perm_args[args.src_format][args.dst_format], result);
@@ -244,7 +244,7 @@ Status FormatTransferTranspose::TransShape(Format src_format, const std::vector<
  std::vector<int64_t> perm_arg;
  GE_CHK_STATUS_RET_NOLOG(GetPermByForamt(src_format, dst_format, perm_arg));
  if (!IsShapeArgValid(src_shape, perm_arg)) {
    return ACL_ERROR_GE_TRANSSHAPE_SHAPE_INVALID;
    return ACL_ERROR_GE_SHAPE_INVALID;
  }
  dst_shape = TransShapeByPerm(src_shape, perm_arg);
  return SUCCESS;
--- a/ge/common/formats/formats.cc
+++ b/ge/common/formats/formats.cc
@@ -38,14 +38,14 @@ GE_FUNC_DEV_VISIBILITY GE_FUNC_HOST_VISIBILITY Status TransFormat(const TransArg
    std::string error = "Failed to trans data from format " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  auto src_shape_size = GetItemNumByShape(args.src_shape);
  if (args.data == nullptr && src_shape_size != 0) {
    GELOGE(PARAM_INVALID, "Invalid input null data");
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Invalid input null data");
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  return transfer->TransFormat(args, result);
@@ -64,8 +64,8 @@ GE_FUNC_DEV_VISIBILITY GE_FUNC_HOST_VISIBILITY Status TransShape(Format src_form
    std::string error = "Failed to trans data from format " +
        FmtToStr(TypeUtils::FormatToSerialString(args.src_format)) + " to " +
        FmtToStr(TypeUtils::FormatToSerialString(args.dst_format));
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_TRANSSHAPE_FORMAT_INVALID;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_FORMAT_INVALID, error.c_str());
    return ACL_ERROR_GE_FORMAT_INVALID;
  }
  return transfer->TransShape(src_format, src_shape, data_type, dst_format, dst_shape);
@@ -77,13 +77,13 @@ GE_FUNC_DEV_VISIBILITY GE_FUNC_HOST_VISIBILITY Status TransDataType(const CastAr
    std::string error = "Failed to trans data from datatype " +
        FmtToStr(TypeUtils::DataTypeToSerialString(args.src_data_type)) + " to " +
        FmtToStr(TypeUtils::DataTypeToSerialString(args.dst_data_type));
    GE_ERRORLOG_AND_ERRORMSG(UNSUPPORTED, error.c_str());
    return UNSUPPORTED;
    GE_ERRORLOG_AND_ERRORMSG(ACL_ERROR_GE_DATATYPE_INVALID, error.c_str());
    return ACL_ERROR_GE_DATATYPE_INVALID;
  }
  if (args.data == nullptr && args.src_data_size != 0) {
    GELOGE(PARAM_INVALID, "Invalid input null data");
    return PARAM_INVALID;
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Invalid input null data");
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  return transfer->TransDataType(args, result);
--- a/ge/common/ge/plugin_manager.cc
+++ b/ge/common/ge/plugin_manager.cc
@@ -53,6 +53,7 @@ string PluginManager::GetPath() {
    GELOGW("Failed to read the shared library file path!");
    return string();
  } else {
    GE_IF_BOOL_EXEC(dl_info.dli_fname == nullptr, return string());
    std::string so_path = dl_info.dli_fname;
    char path[MMPA_MAX_PATH] = {0};
    if (so_path.length() >= MMPA_MAX_PATH) {
--- a/ge/common/helper/model_cache_helper.cc
+++ b/ge/common/helper/model_cache_helper.cc
@@ -14,22 +14,15 @@
 * limitations under the License.
 */
 #include <climits>
 #include "common/helper/model_cache_helper.h"
 #include <cstdio>
 #include <fstream>
 #include <functional>
 #include "common/ge/ge_util.h"
 #include "common/helper/model_cache_helper.h"
 #include "common/types.h"
 #include "framework/common/debug/ge_log.h"
 #include "framework/common/ge_types.h"
 #include "common/model_parser/model_parser.h"
 #include "framework/common/helper/model_helper.h"
 #include "framework/common/util.h"
 #include "graph/detail/attributes_holder.h"
 #include "graph/detail/model_serialize_imp.h"
 #include "graph/load/model_manager/davinci_model_parser.h"
 #include "graph/model.h"
 #include "graph/utils/graph_utils.h"
 #include "graph/utils/tensor_utils.h"
 #include "init/gelib.h"
@@ -1682,7 +1675,7 @@ Status ModelCacheHelper::LoadOmModelFromCache(GeModelPtr &ge_model) const {
  string key_path;
  int32_t priority = 0;
  ModelData model_data;
  ret = DavinciModelParser::LoadFromFile(om_path.c_str(), key_path.c_str(), priority, model_data);
  ret = ModelParserBase::LoadFromFile(om_path.c_str(), key_path.c_str(), priority, model_data);
  if (ret != SUCCESS) {
    GELOGW("LoadOmModelFromCache: Load model from file failed. ret = %u", ret);
    return ret;
--- a/ge/common/helper/model_helper.cc
+++ b/ge/common/helper/model_helper.cc
@@ -16,15 +16,10 @@
 #include "framework/common/helper/model_helper.h"
 #include "common/ge/ge_util.h"
 #include "common/util/error_manager/error_manager.h"
 #include "framework/common/debug/log.h"
 #include "framework/common/util.h"
 #include "framework/common/debug/ge_log.h"
 #include "common/model_parser/model_parser.h"
 #include "framework/omg/model_tool.h"
 #include "framework/omg/version.h"
 #include "graph/debug/ge_attr_define.h"
 #include "graph/load/model_manager/davinci_model_parser.h"
 #include "graph/utils/attr_utils.h"
 #include "graph/utils/graph_utils.h"
 using std::string;
@@ -464,7 +459,7 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status ModelHelper::LoadModel(c
    return ACL_ERROR_GE_EXEC_RELEASE_MODEL_DATA;
  }
  Status status = ge::DavinciModelParser::ParseModelContent(model_data, model_addr_tmp_, model_len_tmp_);
  Status status = ModelParserBase::ParseModelContent(model_data, model_addr_tmp_, model_len_tmp_);
  if (status != SUCCESS) {
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Parse model content failed!");
    return ACL_ERROR_GE_PARAM_INVALID;
@@ -513,7 +508,7 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status ModelHelper::LoadRootMod
    return INTERNAL_ERROR;
  }
  Status status = ge::DavinciModelParser::ParseModelContent(model_data, model_addr_tmp_, model_len_tmp_);
  Status status = ModelParserBase::ParseModelContent(model_data, model_addr_tmp_, model_len_tmp_);
  if (status != SUCCESS) {
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Parse model content failed!");
    return ACL_ERROR_GE_PARAM_INVALID;
@@ -879,4 +874,97 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status ModelHelper::GetModelNam
  GE_CHK_BOOL_EXEC_WARN(!model_name.empty(), return FAILED, "Get model_name failed, check params --output");
  return SUCCESS;
 }
 Status ModelTool::GetModelInfoFromOm(const char *model_file, ge::proto::ModelDef &model_def, uint32_t &modeldef_size) {
  GE_CHECK_NOTNULL(model_file);
  ge::ModelData model;
  int32_t priority = 0;
  Status ret = ModelParserBase::LoadFromFile(model_file, "", priority, model);
  if (ret != SUCCESS) {
    GELOGE(ret, "LoadFromFile failed.");
    return ret;
  }
  std::function<void()> callback = [&]() {
    if (model.model_data != nullptr) {
      delete[] reinterpret_cast<char *>(model.model_data);
      model.model_data = nullptr;
    }
  };
  GE_MAKE_GUARD(release, callback);
  uint8_t *model_data = nullptr;
  uint32_t model_len = 0;
  ret = ModelParserBase::ParseModelContent(model, model_data, model_len);
  if (ret != SUCCESS) {
    ErrorManager::GetInstance().ATCReportErrMessage("E10003",
      {"parameter", "value", "reason"}, {"om", model_file, "invalid om file"});
    GELOGE(ACL_ERROR_GE_PARAM_INVALID,
           "ParseModelContent failed because of invalid om file. Please check --om param.");
    return ret;
  }
  OmFileLoadHelper om_load_helper;
  ret = om_load_helper.Init(model_data, model_len);
  if (ret != SUCCESS) {
    ErrorManager::GetInstance().ATCReportErrMessage("E19021", {"reason"}, {"Om file init failed"});
    GELOGE(ge::FAILED, "Om file init failed.");
    return ret;
  }
  ModelPartition ir_part;
  ret = om_load_helper.GetModelPartition(MODEL_DEF, ir_part);
  if (ret != SUCCESS) {
    ErrorManager::GetInstance().ATCReportErrMessage("E19021", {"reason"}, {"Get model part failed"});
    GELOGE(ge::FAILED, "Get model part failed.");
    return ret;
  }
  bool flag = ReadProtoFromArray(ir_part.data, ir_part.size, &model_def);
  if (!flag) {
    ret = INTERNAL_ERROR;
    ErrorManager::GetInstance().ATCReportErrMessage("E19021", {"reason"}, {"ReadProtoFromArray failed"});
    GELOGE(ret, "ReadProtoFromArray failed.");
    return ret;
  }
  modeldef_size = ir_part.size;
  return ret;
 }
 Status ModelTool::GetModelInfoFromPbtxt(const char *model_file, ge::proto::ModelDef &model_def) {
  GE_CHECK_NOTNULL(model_file);
  ge::ModelData model;
  int32_t priority = 0;
  Status ret = ModelParserBase::LoadFromFile(model_file, "", priority, model);
  auto free_model_data = [](void **ptr) -> void {
    if (ptr != nullptr && *ptr != nullptr) {
      delete[] reinterpret_cast<char *>(*ptr);
      *ptr = nullptr;
    }
  };
  if (ret != SUCCESS) {
    free_model_data(&model.model_data);
    GELOGE(ret, "LoadFromFile failed.");
    return ret;
  }
  try {
    bool flag = google::protobuf::TextFormat::ParseFromString(reinterpret_cast<char *>(model.model_data), &model_def);
    if (!flag) {
      free_model_data(&model.model_data);
      ErrorManager::GetInstance().ATCReportErrMessage("E19021", {"reason"}, {"ParseFromString failed"});
      GELOGE(FAILED, "ParseFromString failed.");
      return FAILED;
    }
    free_model_data(&model.model_data);
    return SUCCESS;
  } catch (google::protobuf::FatalException &e) {
    free_model_data(&model.model_data);
    ErrorManager::GetInstance().ATCReportErrMessage("E19021", {"reason"}, {"ParseFromString failed, exception message["
                                                    + std::string(e.what()) + "]"});
    GELOGE(FAILED, "ParseFromString failed. exception message : %s", e.what());
    return FAILED;
  }
 }
 }  // namespace ge
--- a/ge/common/helper/om_file_helper.cc
+++ b/ge/common/helper/om_file_helper.cc
@@ -165,7 +165,7 @@ Status OmFileLoadHelper::LoadModelPartitionTable(uint8_t *model_data, const uint
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  size_t mem_offset = SIZE_OF_MODEL_PARTITION_TABLE(*partition_table);
  GELOGD("ModelPartitionTable num :%u, ModelFileHeader length :%zu, ModelPartitionTable length :%zu",
  GELOGD("ModelPartitionTable num:%u, ModelFileHeader length:%zu, ModelPartitionTable length:%zu",
         partition_table->num, sizeof(ModelFileHeader), mem_offset);
  if (model_data_size <= mem_offset) {
    GELOGE(ACL_ERROR_GE_EXEC_MODEL_DATA_SIZE_INVALID, "invalid model data, partition_table->num:%u, model data size %u",
@@ -207,7 +207,8 @@ Status OmFileLoadHelper::LoadModelPartitionTable(uint8_t *model_data, uint32_t m
           "ModelFileHeader length :%zu, ModelPartitionTable length :%zu",
           index, partition_table->num, sizeof(ModelFileHeader), partition_table_size);
    if (model_data_size <= cur_offset) {
      GELOGE(ACL_ERROR_GE_EXEC_MODEL_DATA_SIZE_INVALID, "invalid model data, partition_table->num:%u, model data size %u",
      GELOGE(ACL_ERROR_GE_EXEC_MODEL_DATA_SIZE_INVALID,
             "invalid model data, partition_table->num:%u, model data size %u",
             partition_table->num, model_data_size);
      return ACL_ERROR_GE_EXEC_MODEL_DATA_SIZE_INVALID;
    }
--- a/ge/common/model_parser/model_parser.cc
+++ b/ge/common/model_parser/model_parser.cc
@@ -14,16 +14,13 @@
 * limitations under the License.
 */
 #include "common/model_parser/base.h"
 #include "common/helper/model_helper.h"
 #include <securec.h>
 #include "common/model_parser/model_parser.h"
 #include <fstream>
 #include <memory>
 #include <string>
 #include "framework/common/debug/ge_log.h"
 #include "framework/common/debug/log.h"
 #include "framework/common/util.h"
 #include "securec.h"
 #include "common/helper/model_helper.h"
 namespace ge {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY ModelParserBase::ModelParserBase() {}
--- a/ge/common/model_parser/model_parser.h
+++ b/ge/common/model_parser/model_parser.h
--- a/ge/common/profiling/profiling_manager.cc
+++ b/ge/common/profiling/profiling_manager.cc
@@ -20,6 +20,8 @@
 #include "framework/common/debug/log.h"
 #include "framework/common/string_util.h"
 #include "graph/ge_context.h"
 #include "graph/utils/type_utils.h"
 #include "graph/types.h"
 #include "runtime/base.h"
 #include "graph/load/model_manager/davinci_model.h"
@@ -31,12 +33,30 @@ const char *const kBpPoint = "bp_point";
 #ifdef DAVINCI_SUPPORT_PROFILING
 const size_t kReportMaxLen = 2048;
 const int32_t kMaxDeviceNum = 256;
 const uint32_t kInteval = 2;
 const std::string kConfigNumsdev = "devNums";
 const std::string kConfigDevIdList = "devIdList";
 const std::string kProfStart = "prof_start";
 const std::string kProfStop = "prof_stop";
 const std::string kProfModelSubscribe = "prof_model_subscribe";
 const std::string kProfModelUnsubscribe = "prof_model_cancel_subscribe";
 const std::string kModelName = "model_name";
 const std::string kModelId = "model_id";
 const std::string kOpNmae = "op_name";
 const std::string kOptype = "op_type";
 const std::string kBlockDim = "block_dims";
 const std::string kTaskId = "task_id";
 const std::string kStreamId = "stream_id";
 const std::string kShapeType = "shape_type";
 const std::string kCurIterNum = "cur_iter_num";
 const std::string kTaskType = "task_type";
 const std::string kInput = "input";
 const std::string kOutput = "output";
 const std::string kFormat = "format";
 const std::string kDataType = "data_type";
 const std::string kShape = "shape";
 const std::string kIdx = "idx";
 #endif
 }  // namespace
@@ -206,118 +226,69 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::StopProf
 #endif
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::ProfilingTaskDescInfo(
    uint32_t model_id, const std::vector<TaskDescInfo> &task_desc_info, const int32_t &device_id) {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::ProfilingOpInputOutInfo(
    const TaskDescInfo &task, Json &task_json) {
 #ifdef DAVINCI_SUPPORT_PROFILING
  std::string data;
  for (const auto &task : task_desc_info) {
    std::string model_name = task.model_name;
    std::string op_name = task.op_name;
    uint32_t block_dim = task.block_dim;
    uint32_t task_id = task.task_id;
    uint32_t stream_id = task.stream_id;
    std::string shape_type = task.shape_type;
    int64_t cur_iter_num = task.cur_iter_num;
    uint32_t task_type = task.task_type;
    data = model_name.append(" ")
                     .append(op_name).append(" ")
                     .append(std::to_string(block_dim)).append(" ")
                     .append(std::to_string(task_id)).append(" ")
                     .append(std::to_string(stream_id)).append(" ")
                     .append(std::to_string(model_id)).append(" ")
                     .append(shape_type).append(" ")
                     .append(std::to_string(cur_iter_num)).append(" ")
                     .append(std::to_string(task_type)).append("\n");
    ReporterData reporter_data{};
    reporter_data.deviceId = device_id;
    reporter_data.data = (unsigned char *)data.c_str();
    reporter_data.dataLen = data.size();
    int ret = memcpy_s(reporter_data.tag, MSPROF_ENGINE_MAX_TAG_LEN + 1, "task_desc_info", sizeof("task_desc_info"));
    if (ret != EOK) {
      GELOGE(ret, "Report data tag of task_desc_info memcpy error!");
      return;
    }
    int32_t cb_ret = CallMsprofReport(reporter_data);
    if (cb_ret != 0) {
      GELOGE(cb_ret, "Reporter data of task_desc_info failed, ret:%d", cb_ret);
      return;
    }
  for (size_t i = 0; i < task.input_format.size(); i++) {
    Json tmp_input;
    tmp_input[kIdx] = i;
    Format format = task.input_format[i];
    tmp_input[kFormat] = TypeUtils::FormatToSerialString(format);
    DataType data_type = task.input_data_type[i];
    tmp_input[kDataType] = TypeUtils::DataTypeToSerialString(data_type);
    tmp_input[kShape] = task.input_shape[i];
    task_json[kInput] += tmp_input;
  }
  for (size_t i = 0; i < task.output_format.size(); i++) {
    Json tmp_output;
    tmp_output[kIdx] = i;
    Format format = task.output_format[i];
    tmp_output[kFormat] =  TypeUtils::FormatToSerialString(format);
    DataType data_type = task.output_data_type[i];
    tmp_output[kDataType] = TypeUtils::DataTypeToSerialString(data_type);
    tmp_output[kShape] = task.output_shape[i];
    task_json[kOutput] += tmp_output;
  }
  data.clear();
 #endif
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::ProfilingGraphDescInfo(
    uint32_t model_id, const std::vector<ComputeGraphDescInfo> &compute_graph_desc_info, const int32_t &device_id) {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::ProfilingTaskDescInfo(
  uint32_t model_id, const std::vector<TaskDescInfo> &task_desc_info, const int32_t &device_id) {
 #ifdef DAVINCI_SUPPORT_PROFILING
  std::string data;
  for (const auto &graph : compute_graph_desc_info) {
    data.append("model_name:")
        .append(graph.model_name)
        .append(" op_name:")
        .append(graph.op_name)
        .append(" op_type:")
        .append(graph.op_type);
    for (size_t i = 0; i < graph.input_format.size(); ++i) {
      data.append(" input_id:")
          .append(std::to_string(i))
          .append(" input_format:")
          .append(std::to_string(graph.input_format.at(i)))
          .append(" input_data_type:")
          .append(std::to_string(graph.input_data_type.at(i)))
          .append(" input_shape:\"");
      size_t input_shape_len = graph.input_shape.at(i).size();
      if (input_shape_len == 0) {
        data.append("");
      } else if (input_shape_len == 1) {
        data.append(std::to_string(graph.input_shape.at(i).at(0)));
      } else {
        for (size_t j = 0; j < input_shape_len - 1; ++j) {
          data.append(std::to_string(graph.input_shape.at(i).at(j))).append(",");
        }
        data.append(std::to_string(graph.input_shape.at(i).at(input_shape_len - 1)));
      }
      data.append("\"");
    }
    for (size_t i = 0; i < graph.output_format.size(); ++i) {
      data.append(" output_id:")
          .append(std::to_string(i))
          .append(" output_format:")
          .append(std::to_string(graph.output_format.at(i)))
          .append(" output_data_type:")
          .append(std::to_string(graph.output_data_type.at(i)))
          .append(" output_shape:\"");
      size_t output_shape_len = graph.output_shape.at(i).size();
      if (output_shape_len == 0) {
        data.append("");
      } else if (output_shape_len == 1) {
        data.append(std::to_string(graph.output_shape.at(i).at(0)));
      } else {
        for (size_t j = 0; j < output_shape_len - 1; ++j) {
          data.append(std::to_string(graph.output_shape.at(i).at(j))).append(",");
        }
        data.append(std::to_string(graph.output_shape.at(i).at(output_shape_len - 1)));
      }
      data.append("\"");
  for (const auto &task : task_desc_info) {
    Json task_info;
    task_info[kModelName] = task.model_name;
    task_info[kModelId] = model_id;
    task_info[kOpNmae] = task.op_name;
    task_info[kOptype] = task.op_type;
    task_info[kBlockDim] = task.block_dim;
    task_info[kTaskType] = task.task_type;
    task_info[kTaskId] = task.task_id;
    task_info[kStreamId] = task.stream_id;
    task_info[kCurIterNum] = task.cur_iter_num;
    task_info[kShapeType] = task.shape_type;
    ProfilingOpInputOutInfo(task, task_info);
    std::string reported_data;
    try {
      reported_data = task_info.dump(kInteval, ' ', false, Json::error_handler_t::ignore);
    } catch (std::exception &e) {
      GELOGE(FAILED, "Failed to convert JSON to string, reason: %s.", e.what());
      return ;
    } catch (...) {
      GELOGE(FAILED, "Failed to convert JSON to string.");
      return;
    }
    data.append(" model_id:").append(std::to_string(model_id));
    data.append(" task_id:").append(std::to_string(graph.task_id));
    data.append(" stream_id:").append(std::to_string(graph.stream_id));
    data.append("\n");
    GraphDescReport(device_id, data);
    data.clear();
    reported_data.append(",")
                 .append("\n");
    ReportData(device_id, reported_data, "task_desc_info");
  }
 #endif
 }
 void ProfilingManager::GraphDescReport(const int32_t &device_id, const string &data) {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::ReportData(
    const int32_t &device_id, const string &data, const string &tag_name) {
 #ifdef DAVINCI_SUPPORT_PROFILING
  ReporterData reporter_data{};
  int ret = -1;
@@ -325,36 +296,38 @@ void ProfilingManager::GraphDescReport(const int32_t &device_id, const string &d
  size_t index = data.size() / kReportMaxLen;
  if (index >= 1) {
    reporter_data.deviceId = device_id;
    ret = memcpy_s(reporter_data.tag, MSPROF_ENGINE_MAX_TAG_LEN + 1, "graph_desc_info", sizeof("graph_desc_info"));
    GE_IF_BOOL_EXEC(ret != EOK, GELOGE(ret, "Report data tag of graph_desc_info memcpy error!"); return;);
    ret = memcpy_s(reporter_data.tag, MSPROF_ENGINE_MAX_TAG_LEN + 1, tag_name.c_str(), tag_name.size());
    GE_IF_BOOL_EXEC(ret != EOK, GELOGE(ret, "Report data tag [%s] memcpy error!", tag_name.c_str()); return;);
    for (size_t i = 0; i < index; ++i) {
      reporter_data.data = (unsigned char *)data.c_str() + kReportMaxLen * i;
      reporter_data.dataLen = kReportMaxLen;
      cb_ret = CallMsprofReport(reporter_data);
      GE_IF_BOOL_EXEC(cb_ret != 0, GELOGE(cb_ret, "Reporter data of graph_desc_info failed, ret:%d", cb_ret); return;);
      GE_IF_BOOL_EXEC(cb_ret != 0, GELOGE(cb_ret, "Reporter data [%s] failed, ret:%d", tag_name.c_str(), cb_ret);
                      return;);
    }
    reporter_data.dataLen = data.size() - kReportMaxLen * index;
    if (reporter_data.dataLen != 0) {
      reporter_data.data = (unsigned char *)data.c_str() + kReportMaxLen * index;
      cb_ret = CallMsprofReport(reporter_data);
      GE_IF_BOOL_EXEC(cb_ret != 0, GELOGE(cb_ret, "Reporter data of graph_desc_info failed, ret:%d", cb_ret); return;);
      GE_IF_BOOL_EXEC(cb_ret != 0, GELOGE(cb_ret, "Reporter data [%s] failed, ret:%d", tag_name.c_str(), cb_ret);
                      return;);
    }
  } else {
    reporter_data.deviceId = device_id;
    reporter_data.data = (unsigned char *)data.c_str();
    reporter_data.dataLen = data.size();
    ret = memcpy_s(reporter_data.tag, MSPROF_ENGINE_MAX_TAG_LEN + 1, "graph_desc_info", sizeof("graph_desc_info"));
    GE_IF_BOOL_EXEC(ret != EOK, GELOGE(ret, "Report data tag of graph_desc_info memcpy error!"); return;);
    ret = memcpy_s(reporter_data.tag, MSPROF_ENGINE_MAX_TAG_LEN + 1, tag_name.c_str(), tag_name.size());
    GE_IF_BOOL_EXEC(ret != EOK, GELOGE(ret, "Report data tag [%s] memcpy error!", tag_name.c_str()); return;);
    cb_ret = CallMsprofReport(reporter_data);
    GE_IF_BOOL_EXEC(cb_ret != 0, GELOGE(cb_ret, "Reporter data of graph_desc_info failed, ret:%d", cb_ret); return;);
    GE_IF_BOOL_EXEC(cb_ret != 0, GELOGE(cb_ret, "Reporter data [%s] failed, ret:%d", tag_name.c_str(), cb_ret);
                    return;);
  }
 #endif
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::ReportProfilingData(
    uint32_t model_id, const std::vector<TaskDescInfo> &task_desc_info,
    const std::vector<ComputeGraphDescInfo> &compute_graph_desc_info) {
    uint32_t model_id, const std::vector<TaskDescInfo> &task_desc_info) {
 #ifdef DAVINCI_SUPPORT_PROFILING
  int32_t logic_device_id = 0;
  rtError_t rt_ret = rtGetDevice(&logic_device_id);
@@ -365,8 +338,6 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::ReportPr
  GELOGD("current logic_device_id:%d", logic_device_id);
  GELOGD("start ProfilingTaskDescInfo.");
  ProfilingTaskDescInfo(model_id, task_desc_info, logic_device_id);
  GELOGD("start ProfilingGraphDescInfo.");
  ProfilingGraphDescInfo(model_id, compute_graph_desc_info, logic_device_id);
  GELOGD("Report profiling data for GE end.");
 #endif
 }
@@ -813,6 +784,44 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY Status ProfilingManager::CallMs
      static_cast<void *>(&reporter_data), sizeof(ReporterData));
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::GetOpInputOutputInfo(
    const OpDescPtr &op, TaskDescInfo &task_desc_info) const {
  std::vector<Format> input_format;
  std::vector<std::vector<int64_t>> input_shape;
  std::vector<DataType> input_data_type;
  for (size_t i = 0; i < op->GetAllInputsSize(); ++i) {
    GeTensorDescPtr input_tensor_desc = op->MutableInputDesc(i);
    if (input_tensor_desc == nullptr) {
      continue;
    }
    input_format.emplace_back(input_tensor_desc->GetFormat());
    input_shape.emplace_back(input_tensor_desc->GetShape().GetDims());
    input_data_type.emplace_back(input_tensor_desc->GetDataType());
  }
  std::vector<Format> output_format;
  std::vector<std::vector<int64_t>> output_shape;
  std::vector<DataType> output_data_type;
  for (size_t j = 0; j < op->GetOutputsSize(); ++j) {
    GeTensorDescPtr output_tensor_desc = op->MutableOutputDesc(j);
    if (output_tensor_desc == nullptr) {
      continue;
    }
    output_format.emplace_back(output_tensor_desc->GetFormat());
    output_shape.emplace_back(output_tensor_desc->GetShape().GetDims());
    output_data_type.emplace_back(output_tensor_desc->GetDataType());
  }
  std::vector<Format> format_default =  { FORMAT_NULL };
  std::vector<std::vector<int64_t>> shape_default = { {0} };
  std::vector<DataType> data_type_default = { DT_UNDEFINED };
  task_desc_info.input_format = input_format.empty() ? format_default : input_format;
  task_desc_info.input_shape = input_shape.empty() ? shape_default : input_shape;
  task_desc_info.input_data_type = input_data_type.empty() ? data_type_default : input_data_type;
  task_desc_info.output_format = output_format.empty() ? format_default : output_format;
  task_desc_info.output_shape = output_shape.empty() ? shape_default : output_shape;
  task_desc_info.output_data_type = output_data_type.empty() ? data_type_default : output_data_type;
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void ProfilingManager::GetFpBpPoint(
    std::string &fp_point, std::string &bp_point) {
  // Env or options mode, fp_point_/bp_point_ have initiliazed on profiling init
--- a/ge/common/profiling/profiling_manager.h
+++ b/ge/common/profiling/profiling_manager.h
@@ -54,6 +54,8 @@ namespace {
 }  // namespace
 namespace ge {
 class OpDesc;
 using OpDescPtr = std::shared_ptr<OpDesc>;
 struct DeviceSubsInfo {
  uint64_t module;
  uint32_t subscribe_count;
@@ -82,12 +84,10 @@ class FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY ProfilingManager {
  bool ProfilingModelExecuteOn() const;
  // is_execute_profiling_ only used by ge option and env
  bool ProfilingOn() const { return is_load_profiling_ && is_execute_profiling_; }
  void ReportProfilingData(uint32_t model_id, const std::vector<TaskDescInfo> &task_desc_info,
                           const std::vector<ComputeGraphDescInfo> &compute_graph_desc_info);
  void ReportProfilingData(uint32_t model_id, const std::vector<TaskDescInfo> &task_desc_info);
  void ProfilingTaskDescInfo(uint32_t model_id, const std::vector<TaskDescInfo> &task_desc_info,
                             const int32_t &device_id);
  void ProfilingGraphDescInfo(uint32_t model_id, const std::vector<ComputeGraphDescInfo> &compute_graph_desc_info,
                              const int32_t &device_id);
  void ProfilingOpInputOutInfo(const TaskDescInfo &task, Json &task_json);
  Status PluginInit() const;
  void PluginUnInit() const;
  Status CallMsprofReport(ReporterData &reporter_data) const;
@@ -95,6 +95,8 @@ class FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY ProfilingManager {
  void SetMsprofCtrlCallback(MsprofCtrlCallback func) { prof_cb_.msprofCtrlCallback = func; }
  void SetMsprofReporterCallback(MsprofReporterCallback func) { prof_cb_.msprofReporterCallback = func; }
  void GetFpBpPoint(std::string &fp_point, std::string &bp_point);
  void GetOpInputOutputInfo(const OpDescPtr &op, TaskDescInfo &task_desc_info) const;
  void ReportData(const int32_t &device_id, const std::string &data, const std::string &tag_name);
 private:
  Status InitFromOptions(const Options &options, MsprofGeOptions &prof_conf);
  Status ParseOptions(const std::string &options);
@@ -103,7 +105,6 @@ class FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY ProfilingManager {
  Status ProfParseDeviceId(const std::map<std::string, std::string> &config_para,
                               vector<int32_t> &device_list);
  uint64_t GetProfilingModule();
  void GraphDescReport(const int32_t &device_id, const string &data);
  void UpdateDeviceIdModuleMap(string prof_type, uint64_t module, const vector<int32_t> &device_list);
  void UpdateSubscribeDeviceModuleMap(std::string prof_type, uint32_t device_id, uint64_t module);
--- a/ge/common/properties_manager.cc
+++ b/ge/common/properties_manager.cc
@@ -165,24 +165,4 @@ FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void PropertiesManager::SetProp
  delimiter = de;
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY DumpProperties &PropertiesManager::GetDumpProperties(
    uint64_t session_id) {
  std::lock_guard<std::mutex> lock(mutex_);
  // If session_id is not found in dump_properties_map_, operator[] will insert one.
  return dump_properties_map_[session_id];
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void PropertiesManager::AddDumpProperties(
    uint64_t session_id, const DumpProperties &dump_properties) {
  std::lock_guard<std::mutex> lock(mutex_);
  dump_properties_map_.emplace(session_id, dump_properties);
 }
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY void PropertiesManager::RemoveDumpProperties(uint64_t session_id) {
  std::lock_guard<std::mutex> lock(mutex_);
  auto iter = dump_properties_map_.find(session_id);
  if (iter != dump_properties_map_.end()) {
    dump_properties_map_.erase(iter);
  }
 }
 }  // namespace ge
--- a/ge/common/properties_manager.h
+++ b/ge/common/properties_manager.h
@@ -83,13 +83,6 @@ class PropertiesManager {
   */
  void SetPropertyDelimiter(const std::string &de);
  DumpProperties &GetDumpProperties(uint64_t session_id);
  const map<uint64_t, DumpProperties> &GetDumpPropertiesMap() { return dump_properties_map_; }
  void AddDumpProperties(uint64_t session_id, const DumpProperties &dump_properties);
  void RemoveDumpProperties(uint64_t session_id);
 private:
  // Private construct, destructor
  PropertiesManager();
@@ -111,8 +104,6 @@ class PropertiesManager {
  std::map<std::string, std::string> properties_map_;
  std::mutex mutex_;
  std::map<uint64_t, DumpProperties> dump_properties_map_;
 };
 }  // namespace ge
--- a/ge/engine_manager/dnnengine_manager.cc
+++ b/ge/engine_manager/dnnengine_manager.cc
@@ -217,7 +217,7 @@ std::string DNNEngineManager::GetDNNEngineName(const ge::NodePtr &node_ptr) {
      std::string unsupported_reason;
      // It will be replaced by engine' checksupport
      uint64_t start_time = GetCurrentTimestamp();
      if (kernel_info_store->second->CheckSupported(op_desc, unsupported_reason)) {
      if (kernel_info_store->second->CheckSupported(node_ptr, unsupported_reason)) {
        checksupport_cost_[kernel_name] += GetCurrentTimestamp() - start_time;
        op_desc->SetOpEngineName(it.engine);
        op_desc->SetOpKernelLibName(kernel_name);
--- a/ge/executor/CMakeLists.txt
+++ b/ge/executor/CMakeLists.txt
@@ -17,6 +17,7 @@ set(SRC_LIST
    "../common/dump/dump_properties.cc"
    "../common/dump/dump_manager.cc"
    "../common/dump/dump_op.cc"
    "../common/dump/opdebug_register.cc"
    "../common/profiling/ge_profiling.cc"
    "../graph/load/graph_loader.cc"
    "../graph/execute/graph_execute.cc"
@@ -33,7 +34,6 @@ set(SRC_LIST
    "../model/ge_model.cc"
    "../model/ge_root_model.cc"
    "../graph/load/model_manager/davinci_model.cc"
    "../graph/load/model_manager/davinci_model_parser.cc"
    "../graph/load/model_manager/model_manager.cc"
    "../graph/load/model_manager/tbe_handle_store.cc"
    "../graph/load/model_manager/cpu_queue_schedule.cc"
@@ -250,15 +250,14 @@ target_link_options(ge_executor_shared PRIVATE
 target_link_libraries(ge_executor_shared PRIVATE
    $<BUILD_INTERFACE:intf_pub>
    msprofiler
    static_mmpa
    -Wl,--no-as-needed
    ge_common
    runtime
    slog
    mmpa
    graph
    register
    error_manager
    ascend_hal_stub
    ascend_protobuf
    c_sec
    -Wl,--as-needed
--- a/ge/executor/ge_executor.cc
+++ b/ge/executor/ge_executor.cc
@@ -16,7 +16,6 @@
 #include "executor/ge_executor.h"
 #include <cce/cce.h>
 #include <cce/compiler_stub.h>
 #include <ctime>
 #include <iostream>
 #include "common/debug/log.h"
@@ -24,19 +23,11 @@
 #include "common/helper/model_helper.h"
 #include "common/profiling/profiling_manager.h"
 #include "common/dump/dump_manager.h"
 #include "common/util.h"
 #include "framework/common/debug/ge_log.h"
 #include "framework/common/util.h"
 #include "graph/execute/graph_execute.h"
 #include "graph/load/graph_loader.h"
 #include "graph/load/model_manager/davinci_model_parser.h"
 #include "graph/load/model_manager/model_manager.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/model.h"
 #include "graph/utils/graph_utils.h"
 #include "mmpa/mmpa_api.h"
 #include "single_op/single_op_manager.h"
 #include "graph/manager/graph_var_manager.h"
 #include "graph/load/model_manager/davinci_model.h"
 #include "opskernel_manager/ops_kernel_builder_manager.h"
@@ -56,7 +47,7 @@ void GetGeTensorDescFromDomiInfo(std::vector<ge::TensorDesc> &ge_descs,
  uint32_t idx = 0;
  for (auto desc_item : domi_descs) {
    ge::TensorDesc ge_desc;
    ge_desc.SetName(desc_item.name);
    ge_desc.SetName(desc_item.name.c_str());
    ge_desc.SetDataType(static_cast<ge::DataType>(desc_item.data_type));
    ge_desc.SetFormat(static_cast<ge::Format>(formats[idx]));
    std::vector<int64_t> shape_dims;
@@ -454,7 +445,8 @@ Status GeExecutor::GetCurDynamicDims(uint32_t model_id, const vector<uint64_t> &
    if (all_data_dims[i] < 0) {
      cur_dynamic_dims.push_back(dynamic_dims[i]);
    } else if (static_cast<uint64_t>(all_data_dims[i]) != dynamic_dims[i]) {
      GELOGE(ACL_ERROR_GE_DYNAMIC_INPUT_LENGTH_INVALID, "Static dims should be same, index: %zu value: %lu should be %ld",
      GELOGE(ACL_ERROR_GE_DYNAMIC_INPUT_LENGTH_INVALID,
             "Static dims should be same, index: %zu value: %lu should be %ld",
             i, dynamic_dims[i], all_data_dims[i]);
      return ACL_ERROR_GE_DYNAMIC_INPUT_LENGTH_INVALID;
    }
@@ -930,12 +922,22 @@ Status GeExecutor::GetMemAndWeightSize(const void *model_data, size_t model_size
 Status GeExecutor::LoadSingleOp(const std::string &model_name, const ge::ModelData &modelData, void *stream,
                                SingleOp **single_op) {
  return SingleOpManager::GetInstance().GetOpFromModel(model_name, modelData, stream, single_op);
  return LoadSingleOpV2(model_name, modelData, stream, single_op, 0);
 }
 Status GeExecutor::LoadSingleOpV2(const std::string &model_name, const ge::ModelData &modelData, void *stream,
                                  SingleOp **single_op, const uint64_t model_id) {
  return SingleOpManager::GetInstance().GetOpFromModel(model_name, modelData, stream, single_op, model_id);
 }
 Status GeExecutor::LoadDynamicSingleOp(const std::string &model_name, const ge::ModelData &modelData, void *stream,
                                       DynamicSingleOp **single_op) {
  return SingleOpManager::GetInstance().GetDynamicOpFromModel(model_name, modelData, stream, single_op);
  return LoadDynamicSingleOpV2(model_name, modelData, stream, single_op, 0);
 }
 Status GeExecutor::LoadDynamicSingleOpV2(const std::string &model_name, const ge::ModelData &modelData, void *stream,
                                         DynamicSingleOp **single_op, const uint64_t model_id) {
  return SingleOpManager::GetInstance().GetDynamicOpFromModel(model_name, modelData, stream, single_op, model_id);
 }
 Status GeExecutor::ExecuteAsync(SingleOp *executor, const std::vector<DataBuffer> &inputs,
--- a/ge/ge_runtime/runtime_model.cc
+++ b/ge/ge_runtime/runtime_model.cc
@@ -28,7 +28,10 @@
 namespace ge {
 namespace model_runner {
 namespace {
 const int kOffsetUnit = 8;
 const uint32_t kStringHeadElems = 2;
 }  // namespace
 RuntimeModel::~RuntimeModel() {
  GELOGI("RuntimeModel destructor start");
@@ -496,10 +499,15 @@ bool RuntimeModel::InitConstantInfo(std::shared_ptr<DavinciModel> &davinci_model
        return false;
      }
      uint64_t *buff = reinterpret_cast<uint64_t *>(const_cast<char *>(constant->weight_data.data()));
      int64_t offset = elem_num * kOffsetUnit;
      uint32_t head_len = kOffsetUnit * kStringHeadElems;
      if (ge::CheckInt64Uint32MulOverflow(elem_num, head_len) != SUCCESS) {
        GELOGE(FAILED, "Shape size is invalid");
        return false;
      }
      int64_t offset = elem_num * head_len;
      uintptr_t hbm_raw_data_base_addr = reinterpret_cast<uintptr_t>(constant->output_addrs[0]) + offset;
      for (int64_t i = elem_num - 1; i >= 0; --i) {
        buff[i] = hbm_raw_data_base_addr + (buff[i] - buff[0]);
        buff[i * kStringHeadElems] = hbm_raw_data_base_addr + (buff[i * kStringHeadElems] - buff[0]);
      }
    }
--- a/ge/generator/ge_generator.cc
+++ b/ge/generator/ge_generator.cc
@@ -66,7 +66,8 @@ bool ContainsDynamicInpus(const ge::OpDesc &op_desc) {
 }  // namespace
 namespace ge {
 static Status CheckEngineTypeSupport(const OpDescPtr &op_desc, OpEngineType engine_type) {
 static Status CheckEngineTypeSupport(const NodePtr &node, OpEngineType engine_type) {
  const OpDescPtr &op_desc = node->GetOpDesc();
  GE_CHECK_NOTNULL_EXEC(op_desc, return PARAM_INVALID);
  if (engine_type == ENGINE_SYS) {
    GELOGI("CheckEngineType: use default engine.");
@@ -123,7 +124,7 @@ static Status CheckEngineTypeSupport(const OpDescPtr &op_desc, OpEngineType engi
  auto kernel_info_store = kernel_map.find(kernel_name);
  if (kernel_info_store != kernel_map.end()) {
    std::string unsupported_reason;
    if (kernel_info_store->second->CheckSupported(op_desc, unsupported_reason)) {
    if (kernel_info_store->second->CheckSupported(node, unsupported_reason)) {
      op_desc->SetOpEngineName(op_engine_name);
      op_desc->SetOpKernelLibName(kernel_name);
      GELOGI("CheckEngineType:Set OpKernelLibName %s and engine name %s into op_desc %s", kernel_name.c_str(),
@@ -147,7 +148,7 @@ static Status CheckEngineTypeSupport(const OpDescPtr &op_desc, OpEngineType engi
  return FAILED;
 }
 static Status AddInputs(const ComputeGraphPtr &graph, const NodePtr &node, GeTensorDesc &tensor, int32_t index,
 static Status AddInputs(const ComputeGraphPtr &graph, const NodePtr &node, const GeTensorDesc &tensor, int32_t index,
                        bool attr) {
  GE_CHECK_NOTNULL_EXEC(graph, return PARAM_INVALID);
  GE_CHECK_NOTNULL_EXEC(node, return PARAM_INVALID);
@@ -326,6 +327,8 @@ Status GeGenerator::Initialize(const map<string, string> &options, OmgContext &o
    GELOGE(MEMALLOC_FAILED, "Make shared failed");
    return MEMALLOC_FAILED;
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOpsProtoInit);
  string opsproto_path;
  GetOpsProtoPath(opsproto_path);
  GELOGI("Get opsproto path is %s", opsproto_path.c_str());
@@ -374,6 +377,7 @@ Status GeGenerator::Initialize(const map<string, string> &options, OmgContext &o
 }
 Status GeGenerator::Finalize() {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kFinalize, ErrorMessage::kFinalize);
  GE_CHECK_NOTNULL_EXEC(impl_, return PARAM_INVALID);
  Status ret = impl_->graph_manager_.Finalize();
  if (ret != SUCCESS) {
@@ -385,12 +389,14 @@ Status GeGenerator::Finalize() {
 Status GeGenerator::GenerateOfflineModel(const Graph &graph, const string &file_name_prefix,
                                         const vector<GeTensor> &inputs) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGI("Start to generate offline model.");
  ModelBufferData model;
  return GenerateModel(graph, file_name_prefix, inputs, model, true);
 }
 Status GeGenerator::GenerateOnlineModel(const Graph &graph, const vector<GeTensor> &inputs, ModelBufferData &model) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  return GenerateModel(graph, "online", inputs, model, false);
 }
@@ -671,6 +677,8 @@ Status GeGenerator::CheckForSingleOp(OpDescPtr &op_desc, const vector<GeTensor>
 Status GeGenerator::BuildSingleOp(OpDescPtr &op_desc, const vector<GeTensor> &inputs, const vector<GeTensor> &outputs,
                                  const string &model_file_name, OpEngineType engine_type, ModelBufferData &model_buff,
                                  bool is_offline) {
  GE_CHECK_NOTNULL_EXEC(impl_, return PARAM_INVALID);
  impl_->is_offline_ = is_offline;
  if (!is_offline) {
    (void)AttrUtils::SetBool(op_desc, ATTR_SINGLE_OP_SCENE, true);
  }
@@ -690,27 +698,26 @@ Status GeGenerator::BuildSingleOp(OpDescPtr &op_desc, const vector<GeTensor> &in
  OpDescPtr op_desc_tmp = AttrUtils::CloneOpDesc(op_desc);
  GE_CHECK_NOTNULL(op_desc_tmp);
  // 1. check engine type when compile online
  // 1. Create ComputeGraph.
  string name = ge::CurrentTimeInStr() + "_" + model_file_name;
  Graph graph;
  GE_CHK_STATUS(BuildSingleOpGraph(op_desc, inputs, outputs, name, graph), "make graph fail.");
  // 2. check engine type when compile online
  if (model_file_name == kFileNameSuffix) {
    Status ret = CheckEngineTypeSupport(op_desc, engine_type);
    auto comp_graph = GraphUtils::GetComputeGraph(graph);
    GE_CHECK_NOTNULL(comp_graph);
    auto node = comp_graph->FindNode(op_desc->GetName());
    Status ret = CheckEngineTypeSupport(node, engine_type);
    if (ret != SUCCESS) {
      GELOGE(ret, "check engine type failed.");
      return ret;
    }
  }
  // 2. Create ComputeGraph.
  string name = ge::CurrentTimeInStr() + "_" + model_file_name;
  Graph graph;
  if (BuildSingleOpGraph(op_desc, inputs, outputs, name, graph) != ge::SUCCESS) {
    GELOGE(GRAPH_FAILED, "make graph fail.");
    return GRAPH_FAILED;
  }
  GELOGI("ATC parser success in single op build.");
  GeRootModelPtr ge_root_model = nullptr;
  GE_CHECK_NOTNULL_EXEC(impl_, return PARAM_INVALID);
  impl_->is_offline_ = is_offline;
  GE_CHK_STATUS_RET_NOLOG(impl_->BuildModel(graph, inputs, ge_root_model));
  map<string, GeAttrValue> op_attrs = op_desc_tmp->GetAllAttrs();
  GE_CHECK_NOTNULL(ge_root_model);
@@ -723,7 +730,7 @@ Status GeGenerator::BuildSingleOp(OpDescPtr &op_desc, const vector<GeTensor> &in
  const ComputeGraphPtr root_graph = ge_root_model->GetRootGraph();
  GeModelPtr &ge_model = name_to_ge_model.begin()->second;
  GE_CHK_STATUS_RET_NOLOG(CheckDynamicSupport(ge_model, root_graph));
  GELOGD("The opType in op_desc_tmp is [%s]", op_desc_tmp->GetType().c_str());
  GELOGI("After build model, The opType in op_desc_tmp is [%s]", op_desc_tmp->GetType().c_str());
  bool all_shape = false;
  (void)AttrUtils::GetBool(op_desc, kAicpuAllshape, all_shape);
@@ -738,6 +745,7 @@ Status GeGenerator::BuildSingleOp(OpDescPtr &op_desc, const vector<GeTensor> &in
  } else {
    GE_CHK_STATUS_RET_NOLOG(impl_->SaveParams(ge_model, op_desc_tmp->GetType(), op_attrs, inputs, outputs));
  }
  GELOGI("Start save GeModel to Model buffer");
  GE_CHK_STATUS_RET_NOLOG(impl_->SaveModel(model_file_name, ge_model, model_buff));
  return SUCCESS;
 }
@@ -753,10 +761,13 @@ Status GeGenerator::BuildSingleOp(OpDescPtr &op_desc, const vector<GeTensor> &in
 */
 Status GeGenerator::BuildSingleOpModel(OpDescPtr &op_desc, const vector<GeTensor> &inputs,
                                       const vector<GeTensor> &outputs, const string &model_file_name) {
  GELOGI("Start to build single op offline model.");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGI("Start to build single op offline model, input size: %zu, output size: %zu", inputs.size(), outputs.size());
  ModelBufferData model_buff;
  OpEngineType engine_type = ENGINE_SYS;
  return BuildSingleOp(op_desc, inputs, outputs, model_file_name, engine_type, model_buff, true);
  Status status = BuildSingleOp(op_desc, inputs, outputs, model_file_name, engine_type, model_buff, true);
  GELOGI("Finish build single offline model, status: %u", status);
  return status;
 }
 /**
@@ -772,8 +783,11 @@ Status GeGenerator::BuildSingleOpModel(OpDescPtr &op_desc, const vector<GeTensor
 Status GeGenerator::BuildSingleOpModel(OpDescPtr &op_desc, const vector<GeTensor> &inputs,
                                       const vector<GeTensor> &outputs, OpEngineType engine_type,
                                       ModelBufferData &model_buff) {
  GELOGI("Start to build single op online");
  return BuildSingleOp(op_desc, inputs, outputs, kFileNameSuffix, engine_type, model_buff, false);
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGI("Start to build single op online, input size: %zu, output size: %zu", inputs.size(), outputs.size());
  Status status = BuildSingleOp(op_desc, inputs, outputs, kFileNameSuffix, engine_type, model_buff, false);
  GELOGI("Finish build single online model, status: %u", status);
  return status;
 }
 Status GeGenerator::BuildSingleOpGraph(OpDescPtr &op_desc, const vector<GeTensor> &inputs,
@@ -798,8 +812,7 @@ Status GeGenerator::BuildSingleOpGraph(OpDescPtr &op_desc, const vector<GeTensor
    }
  } else {
    for (const auto &in_desc : inputs) {
      GeTensorDesc input_desc = in_desc.GetTensorDesc();
      GE_CHK_STATUS_RET_NOLOG(AddInputs(compute_graph, op_node, input_desc, arg_index, true));
      GE_CHK_STATUS_RET_NOLOG(AddInputs(compute_graph, op_node, in_desc.GetTensorDesc(), arg_index, true));
      arg_index++;
    }
  }
@@ -908,6 +921,7 @@ Status GeGenerator::Impl::BuildModel(const Graph &graph, const vector<GeTensor>
    ret = graph_manager_.BuildGraph(graph_id, inputs, ge_root_model, session_id);
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  if (ret != SUCCESS) {
    GELOGE(GE_GENERATOR_GRAPH_MANAGER_BUILD_GRAPH_FAILED, "GraphManager build graph fail, graph id: %u", graph_id);
    VarManagerPool::Instance().RemoveVarManager(session_id);
--- a/ge/graph/build/graph_builder.cc
+++ b/ge/graph/build/graph_builder.cc
@@ -222,6 +222,7 @@ Status GraphBuilder::BuildForKnownShapeGraph(ComputeGraphPtr &comp_graph,
    return SUCCESS;
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kPreBuild);
  GELOGI("Begin to build known shape graph[%s].", comp_graph->GetName().c_str());
  Status ret = SecondPartition(comp_graph);
  GE_CHK_STATUS_RET(ret, "Graph[%s] second partition Failed.", comp_graph->GetName().c_str());
@@ -252,6 +253,7 @@ Status GraphBuilder::BuildForKnownShapeGraph(ComputeGraphPtr &comp_graph,
  GE_TIMESTAMP_END(BuildModelForGetTask, "GraphBuilder::BuildModelForGetTask");
  GE_DUMP(comp_graph, "AfterBuildModel");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kTaskGenerate);
  GE_TIMESTAMP_START(GetTaskInfo);
  ret = GetTaskInfo(builder, model_ptr, comp_graph, subgraph_map, session_id);
  GE_TIMESTAMP_END(GetTaskInfo, "GraphBuilder::GetTaskInfo");
@@ -261,6 +263,7 @@ Status GraphBuilder::BuildForKnownShapeGraph(ComputeGraphPtr &comp_graph,
    return ret;
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  ge_model_ptr = MakeShared<ge::GeModel>();
  if (ge_model_ptr == nullptr) {
    return MEMALLOC_FAILED;
@@ -320,6 +323,7 @@ Status GraphBuilder::SetConstantInputOffset(ComputeGraphPtr &comp_graph) {
 Status GraphBuilder::BuildForUnknownShapeGraph(ComputeGraphPtr &comp_graph, GeModelPtr &ge_model_ptr,
                                               uint64_t session_id) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kPreBuild);
  GELOGI("Begin to build unknown shape graph[%s].", comp_graph->GetName().c_str());
  Graph2SubGraphInfoList subgraph_map;
  ge::ModelBuilder builder(session_id, comp_graph, subgraph_map, stream_max_parallel_num_, hcom_parallel_, build_mode_);
@@ -352,9 +356,11 @@ Status GraphBuilder::BuildForUnknownShapeGraph(ComputeGraphPtr &comp_graph, GeMo
  GE_CHK_STATUS_RET(builder.BuildModelForGetDynShapeTask(*model_ptr),
                    "Graph[%s] builder BuildModelForGetDynShapeTask() return fail.", comp_graph->GetName().c_str());
  GE_TIMESTAMP_END(BuildModelForGetDynShapeTask, "GraphBuilder::BuildModelForGetDynShapeTask");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kTaskGenerate);
  GE_TIMESTAMP_START(GetTaskInfo);
  Status ret = GetTaskInfo(builder, model_ptr, comp_graph, subgraph_map, session_id);
  GE_TIMESTAMP_END(GetTaskInfo, "GraphBuilder::GetTaskInfo");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GraphUtils::DumpGEGraph(comp_graph, "AfterGetTask");
  GraphUtils::DumpGEGraphToOnnx(*comp_graph, "AfterGetTask");
--- a/ge/graph/build/memory/graph_mem_assigner.cc
+++ b/ge/graph/build/memory/graph_mem_assigner.cc
@@ -157,8 +157,8 @@ ge::Status GraphMemoryAssigner::AssignMemory2HasRefAttrNode() {
 }
 ge::Status CalculateTensorRealSizeAndOutSize(const ge::ConstGeTensorDescPtr &output_desc,
                                                                  int64_t dim_index, int64_t &output_mem_size,
                                                                  int64_t &batch_dim_num, int64_t &out_size) {
                                             int64_t dim_index, int64_t &output_mem_size,
                                             int64_t &batch_dim_num, int64_t &out_size) {
  graphStatus graph_status = ge::TensorUtils::GetSize(*output_desc, out_size);
  if (graph_status != GRAPH_SUCCESS) {
    GELOGE(FAILED, "Opdesc GetSize failed!");
@@ -430,18 +430,18 @@ Status GraphMemoryAssigner::ReAssignContinuousMemory(bool is_loop_graph) {
      GELOGE(FAILED, "node %s has no continuous type!", node->GetName().c_str());
      return FAILED;
    }
    GE_CHK_STATUS_RET(AssignContinuousInputMemoryWithAtomicProcess(node, iter->second),
    GE_CHK_STATUS_RET(AssignContinuousInputMemoryWithAtomicProcess(node, iter->second, true),
                      "Assign node %s continuous input memory failed.", node->GetName().c_str())
  }
  for (auto pair : memory_offset_) {
    GELOGD("After reassign continuous memory, memory type = %ld, memoffset = %zu.", pair.first,
    GELOGD("After reassign continuous memory, memory type = %ld, mem_offset = %zu.", pair.first,
           pair.second.mem_offset_);
  }
  return ge::SUCCESS;
 }
 Status GraphMemoryAssigner::AssignContinuousInputMemory(const ge::NodePtr &node, int64_t &continuous_mem_start,
    int64_t &continuous_mem_size, int64_t memory_type, uint32_t continuous_type) {
    int64_t &continuous_mem_size, int64_t memory_type, uint32_t continuous_type, bool reverse_refresh) {
  GELOGI("Current node %s needs continuous input.", node->GetName().c_str());
  auto iter = memory_offset_.find(memory_type);
  if (iter == memory_offset_.end()) {
@@ -508,12 +508,16 @@ Status GraphMemoryAssigner::AssignContinuousInputMemory(const ge::NodePtr &node,
      std::map<int32_t, int32_t> out2ins;
      GE_CHK_STATUS_RET(GetAllRef(node, out2ins), "Node: %s get all ref failed", node->GetName().c_str());
      // output is beginning offset, set offset for input; only support this case now
      if (out2ins.size() == 1 && out2ins.begin()->second == 0) {
      if ((out2ins.size() == 1) && (out2ins.begin()->second == 0) && (reverse_refresh)) {
        auto peer_output_offset = output_list.at(peer_out_data_anchor->GetIdx());
        output_list.at(peer_out_data_anchor->GetIdx()) = output_list_this.at(out2ins.begin()->first);
        peer_op_desc->SetOutputOffset(output_list);
        GELOGI("Node %s out %d ref in %d input node %s, use output offset %ld update %ld.", node->GetName().c_str(),
               out2ins.begin()->first, out2ins.begin()->second, peer_op_desc->GetName().c_str(),
               output_list_this.at(out2ins.begin()->first), peer_output_offset);
      } else {
        GELOGW("Node %s out %d ref in %d with total ref numbers %zu", node->GetName().c_str(), out2ins.begin()->first,
               out2ins.begin()->second, out2ins.size());
        GELOGD("Node %s out %d ref in %d input node %s with total ref numbers %zu.", node->GetName().c_str(),
               out2ins.begin()->first, out2ins.begin()->second, peer_op_desc->GetName().c_str(), out2ins.size());
      }
      // first input is beginning offset
      mem_offset = output_list.at(peer_out_data_anchor->GetIdx());
@@ -538,7 +542,7 @@ Status GraphMemoryAssigner::AssignContinuousInputMemory(const ge::NodePtr &node,
    }
    GELOGI("[IMAS]Continuous input : Set %s name[%s] optype[%s] output[%d] offset to [%zu] stream_id[%ld] memtype[%ld] "
        "size[%zu] realsize[%ld] nopadding[%d].", node->GetOwnerComputeGraph()->GetName().c_str(),
        "size[%zu] realsize[%ld] nopadding size[%d].", node->GetOwnerComputeGraph()->GetName().c_str(),
        peer_op_desc->GetName().c_str(), node->GetType().c_str(), peer_out_data_anchor->GetIdx(),
        output_list.at(peer_out_data_anchor->GetIdx()), peer_op_desc->GetStreamId(), memory_type,
        is_continuous_input_allocated ? 0UL : align_size, real_size, is_nopadding);
@@ -1535,12 +1539,17 @@ ge::Status GraphMemoryAssigner::GetAllRef(const NodePtr &node, map<int32_t, int3
 bool GraphMemoryAssigner::AssignContinuousInputMemoryWithAtomicProcessDirectly(
  const NodePtr &input_continuous_node, map<NodePtr, uint32_t> &node_2_continuous_type) {
  for (const auto &in_node : input_continuous_node->GetInDataNodes()) {
    if (in_node->GetType() == VARIABLE) {
      GELOGI("node %s 's precursor node %s is variable, do not store.", input_continuous_node->GetName().c_str(),
             in_node->GetName().c_str());
      return true;
    }
    auto iter = node_2_continuous_type.find(in_node);
    // In node's topo order in the front, so function can not be exception
    auto continuous_type = iter->second;
    bool continuous_input = ((continuous_type & kTypeInput) != 0) || ((continuous_type & kTypeInputNoPadding) != 0);
    if (continuous_input) {
      GELOGI("node %s 's precursor node %s need assign continuous input memory, store node firstly.",
      GELOGI("Node %s 's precursor node %s need assign continuous input memory, store node firstly.",
             input_continuous_node->GetName().c_str(), in_node->GetName().c_str());
      return false;
    }
@@ -1550,7 +1559,7 @@ bool GraphMemoryAssigner::AssignContinuousInputMemoryWithAtomicProcessDirectly(
    node_2_continuous_type.emplace(out_node, continuous_type);
    bool continuous_input = ((continuous_type & kTypeInput) != 0) || ((continuous_type & kTypeInputNoPadding) != 0);
    if (continuous_input) {
      GELOGI("node %s 's succeed node %s need assign continuous input memory, store node firstly.",
      GELOGI("Node %s 's succeed node %s need assign continuous input memory, store node firstly.",
             input_continuous_node->GetName().c_str(), out_node->GetName().c_str());
      return false;
    }
@@ -1560,13 +1569,15 @@ bool GraphMemoryAssigner::AssignContinuousInputMemoryWithAtomicProcessDirectly(
 }
 ge::Status GraphMemoryAssigner::AssignContinuousInputMemoryWithAtomicProcess(const NodePtr &input_continuous_node,
                                                                             uint32_t continuous_type) {
                                                                             uint32_t continuous_type,
                                                                             bool reverse_refresh) {
  int64_t mem_clean_start = 0;
  int64_t mem_clean_size = 0;
  int64_t memory_type = RT_MEMORY_HBM;
  GE_CHK_STATUS_RET(GetNodeMemoryType(input_continuous_node, memory_type, "input"), "Get node memory type failed.");
  auto ret = AssignContinuousInputMemory(input_continuous_node, mem_clean_start, mem_clean_size, memory_type, continuous_type);
  auto ret = AssignContinuousInputMemory(input_continuous_node, mem_clean_start, mem_clean_size, memory_type,
                                         continuous_type, reverse_refresh);
  if (ret != ge::SUCCESS) {
    GELOGE(ret, "Assign continuous input memory failed!");
    return ret;
--- a/ge/graph/build/memory/graph_mem_assigner.h
+++ b/ge/graph/build/memory/graph_mem_assigner.h
@@ -131,13 +131,14 @@ class GraphMemoryAssigner {
                                                            std::map<NodePtr, uint32_t> &node_2_continuous_type);
  ge::Status AssignContinuousInputMemoryWithAtomicProcess(const NodePtr &input_continuous_node,
                                                          uint32_t continuous_type);
                                                          uint32_t continuous_type, bool reverse_refresh = false);
  ge::Status FilterAtomicNodesForMemoryAssign(map<string, map<NodePtr, vector<NodePtr>>> &normal_atomic_nodes_map,
                                              map<string, vector<NodePtr>> &connecting_output_atomic_nodes);
  ge::Status AssignContinuousInputMemory(const ge::NodePtr &node, int64_t &continuous_mem_start,
                                         int64_t &continuous_mem_size, int64_t memory_type, uint32_t continuous_type);
                                         int64_t &continuous_mem_size, int64_t memory_type, uint32_t continuous_type,
                                         bool reverse_refresh = false);
  ge::Status AssignContinuousOutputMemory(const ge::NodePtr &node, int64_t memory_type, uint32_t continuous_type);
--- a/ge/graph/build/model_builder.cc
+++ b/ge/graph/build/model_builder.cc
@@ -19,6 +19,7 @@
 #include <set>
 #include <unordered_map>
 #include "common/ge/ge_util.h"
 #include "common/dump/dump_manager.h"
 #include "framework/common/debug/ge_log.h"
 #include "graph/anchor.h"
 #include "graph/attr_value.h"
@@ -260,7 +261,9 @@ Status ModelBuilder::SetInputOutputDesc() {
    GE_IF_BOOL_EXEC(n->GetInAllNodes().empty() && n->GetOutAllNodes().empty(), continue;);
    SetInputIsConst(n);
    if (IsGeLocalOp(n->GetOpDesc())) {
    bool is_unknow = false;
    (void)NodeUtils::GetNodeUnknownShapeStatus(*n, is_unknow);
    if ((IsGeLocalOp(n->GetOpDesc())) && (!is_unknow)) {
      GE_CHK_STATUS_RET(CalcOutputSize(n), "Calculate output size failed");
    }
    ret = AdjustConstWeightSize(n, weight_offset_);
@@ -363,8 +366,11 @@ void ModelBuilder::InitL1FusionOption() {
  string buffer_optimize = "off_optimize";
  graphStatus ret = ge::GetContext().GetOption(BUFFER_OPTIMIZE, buffer_optimize);
  if (ret == GRAPH_SUCCESS) {
    is_l1_fusion_enable_ = (buffer_optimize == "l1_optimize");
    GELOGD("The value of %s is %s.", BUFFER_OPTIMIZE.c_str(), buffer_optimize.c_str());
    bool off_superkernel = false;
    (void)AttrUtils::GetBool(compute_graph_, ATTR_NAME_OFF_SUPERKERNEL_ATTR, off_superkernel);
    is_l1_fusion_enable_ = ((buffer_optimize == "l1_optimize") && (!off_superkernel));
    GELOGI("Compute graph %s the value of %s is %s, superkernel flag %d.", compute_graph_->GetName().c_str(),
           BUFFER_OPTIMIZE.c_str(), buffer_optimize.c_str(), is_l1_fusion_enable_);
  } else {
    GELOGW("The value of %s is empty.", kEnableL1Fusion.c_str());
  }
@@ -429,7 +435,7 @@ Status ModelBuilder::BuildModelDef(ge::Model &model) {
  GE_CHK_BOOL_EXEC(ge::AttrUtils::SetBool(&model, ATTR_NAME_SWITCH_FOR_L1_FUSION, is_l1_fusion_enable_),
                   GELOGE(FAILED, "SetBool of ATTR_NAME_SWITCH_FOR_L1_FUSION failed.");
                   return FAILED);
  const DumpProperties &dump_properties = PropertiesManager::Instance().GetDumpProperties(session_id_);
  const DumpProperties &dump_properties = DumpManager::GetInstance().GetDumpProperties(session_id_);
  bool is_op_debug = dump_properties.IsOpDebugOpen();
  if (is_op_debug) {
    if (!ge::AttrUtils::SetBool(&model, ATTR_OP_DEBUG_FLAG, is_op_debug)) {
@@ -683,6 +689,7 @@ Status ModelBuilder::PreBuildModel() {
 Status ModelBuilder::BuildModelForGetTask(ge::Model &model) {
  GE_CHK_STATUS_RET(AdjustInputTensorFlag(), "AdjustInputTensorFlag failed!");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kStreamAlloc);
  // Assign logical streams.
  StreamAllocator stream_allocator(compute_graph_, subgraphs_);
  GE_TIMESTAMP_START(AssignLogicalStreams);
@@ -690,6 +697,7 @@ Status ModelBuilder::BuildModelForGetTask(ge::Model &model) {
                    "Assign logical streams failed.");
  GE_TIMESTAMP_END(AssignLogicalStreams, "GraphBuilder::AssignLogicalStreams");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kMemoryAlloc);
  // Assign functional op labels.
  auto root_graph = GraphUtils::FindRootGraph(compute_graph_);
  (void)AttrUtils::GetInt(*root_graph, ATTR_MODEL_LABEL_NUM, label_num_);
@@ -700,22 +708,25 @@ Status ModelBuilder::BuildModelForGetTask(ge::Model &model) {
                    "Assign Memory Failed!");
  GE_TIMESTAMP_END(AssignMemory, "GraphBuilder::AssignMemory");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GE_TIMESTAMP_START(SetInputOutputOffset);
  SetInputOutputOffsetPass input_output_offset;
  GE_CHK_STATUS_RET(input_output_offset.Run(compute_graph_), "Set input output offset failed.");
  GE_TIMESTAMP_END(SetInputOutputOffset, "SetInputOutputOffsetPass::Run.");
  GE_TIMESTAMP_END(SetInputOutputOffset, "SetInputOutputOffsetPass::Run");
  // Compile single op in graph build stage
  GE_TIMESTAMP_START(CompileSingleOp);
  GE_CHK_STATUS_RET(CompileSingleOp(), "ATC builder CompileSingleOp() return fail.");
  GE_TIMESTAMP_EVENT_END(CompileSingleOp, "GraphBuilder::CompileSingleOp");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kStreamAlloc);
  // Refresh real streams and insert event nodes.
  GE_TIMESTAMP_START(RefreshRealStream);
  GE_CHK_STATUS_RET(stream_allocator.RefreshRealStream(stream_num_, event_num_), "RefreshRealStream failed.");
  huge_streams_ = stream_allocator.GetHugeStreams();
  GE_TIMESTAMP_END(RefreshRealStream, "GraphBuilder::RefreshRealStream");
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GE_TIMESTAMP_START(MergeWeights);
  GE_CHK_STATUS_RET(MergeWeights(), "MergeWeights Failed!");
  GE_TIMESTAMP_END(MergeWeights, "GraphBuilder::MergeWeights");
--- a/ge/graph/build/task_generator.cc
+++ b/ge/graph/build/task_generator.cc
@@ -852,7 +852,7 @@ Status TaskGenerator::FindProfilingTaskIndex(const ComputeGraphPtr &graph, Profi
  // subgraph  of dynamic graph no need to find index, has been found in parent graph
  if (IsSubGraphOfDynamicGraph(graph)) {
    GELOGI("Graph[%s] is subgraph of dynamic graph, no nned to find index.", graph->GetName().c_str());
    GELOGI("Graph[%s] is subgraph of dynamic graph, no need to find index.", graph->GetName().c_str());
    return SUCCESS;
  }
@@ -1042,7 +1042,7 @@ Status TaskGenerator::InsertProfilingTaskAfter(const OpDescPtr &op_desc, const P
  }
  GELOGD("Insert bp profiling task: %d, insert end profiling task: %d, fp index: %u, bp index: %u, end index size: %zu",
         is_insert_bp_profiling_task, is_insert_end_profiling_task, profiling_point.fp_index, profiling_point.bp_index,
         profiling_point.end_index.size() );
         profiling_point.end_index.size());
  bool is_all_reduce = (op_desc->GetType() == HCOMALLREDUCE || op_desc->GetType() == HVDCALLBACKALLREDUCE);
  if ((profiling_point.bp_index == node_index) || (!is_all_reduce && is_insert_bp_profiling_task)) {
--- a/ge/graph/execute/graph_execute.cc
+++ b/ge/graph/execute/graph_execute.cc
@@ -19,12 +19,8 @@
 #include <memory>
 #include <string>
 #include "common/ge_inner_error_codes.h"
 #include "common/model_parser/base.h"
 #include "graph/load/model_manager/model_manager.h"
 #include "omm/csa_interact.h"
 #include "runtime/dev.h"
 #include "runtime/mem.h"
 namespace ge {
 GraphExecutor::GraphExecutor()
--- a/ge/graph/load/graph_loader.cc
+++ b/ge/graph/load/graph_loader.cc
@@ -20,19 +20,13 @@
 #include <vector>
 #include "common/helper/model_helper.h"
 #include "common/util.h"
 #include "common/model_parser/model_parser.h"
 #include "graph/ge_context.h"
 #include "graph/load/model_manager/davinci_model_parser.h"
 #include "graph/load/model_manager/model_manager.h"
 #include "graph/manager/graph_var_manager.h"
 #include "omm/csa_interact.h"
 #include "runtime/dev.h"
 namespace ge {
 GraphLoader::GraphLoader() = default;
 GraphLoader::~GraphLoader() = default;
 Status GraphLoader::UnloadModel(uint32_t model_id) {
  auto model_manager = ModelManager::GetInstance();
  GE_CHECK_NOTNULL(model_manager);
@@ -120,7 +114,6 @@ Status GraphLoader::GetMaxUsedMemory(uint32_t model_id, uint64_t &max_size) {
 Status GraphLoader::LoadDataFromFile(const std::string &path, const std::string &key_path, int32_t priority,
                                     ModelData &model_data) {
  Status ret;
  if (!CheckInputPathValid(path)) {
    GELOGE(ACL_ERROR_GE_EXEC_MODEL_PATH_INVALID, "model path is invalid: %s", path.c_str());
    return ACL_ERROR_GE_EXEC_MODEL_PATH_INVALID;
@@ -132,16 +125,15 @@ Status GraphLoader::LoadDataFromFile(const std::string &path, const std::string
    return ACL_ERROR_GE_PARAM_INVALID;
  }
  ret = DavinciModelParser::LoadFromFile(path.c_str(), key_path.c_str(), priority, model_data);
  Status ret = ModelParserBase::LoadFromFile(path.c_str(), key_path.c_str(), priority, model_data);
  if (ret != SUCCESS) {
    GELOGE(ret, "LoadModelFromFile: Load failed. ret = %u", ret);
    if (model_data.model_data != nullptr) {
      delete[] static_cast<char *>(model_data.model_data);
      model_data.model_data = nullptr;
    }
    return ret;
  }
    return SUCCESS;
  return ret;
 }
 Status GraphLoader::CommandHandle(const Command &command) {
--- a/ge/graph/load/graph_loader.h
+++ b/ge/graph/load/graph_loader.h
@@ -32,9 +32,9 @@
 namespace ge {
 class GraphLoader {
 public:
  GraphLoader();
  GraphLoader() = default;
  virtual ~GraphLoader();
  virtual ~GraphLoader() = default;
  GraphLoader(const GraphLoader &in) = delete;
--- a/ge/graph/load/model_manager/data_dumper.h
+++ b/ge/graph/load/model_manager/data_dumper.h
@@ -36,21 +36,9 @@
 namespace ge {
 class DataDumper {
 public:
  explicit DataDumper(const RuntimeParam &rsh)
      : model_name_(),
        model_id_(0),
        runtime_param_(rsh),
        dev_mem_load_(nullptr),
        dev_mem_unload_(nullptr),
        op_list_(),
        input_map_(),
        load_flag_(false),
        device_id_(0),
        global_step_(0),
        loop_per_iter_(0),
        loop_cond_(0),
        compute_graph_(nullptr),
        ref_info_() {}
  DataDumper() : runtime_param_{} {}
  explicit DataDumper(const RuntimeParam &rsh) : runtime_param_(rsh) {}
  ~DataDumper();
@@ -105,10 +93,10 @@ class DataDumper {
  // for inference data dump
  std::string om_name_;
  uint32_t model_id_;
  uint32_t model_id_ = 0;
  const RuntimeParam &runtime_param_;
  void *dev_mem_load_;
  void *dev_mem_unload_;
  void *dev_mem_load_ = nullptr;
  void *dev_mem_unload_ = nullptr;
  struct InnerDumpInfo;
  struct InnerInputMapping;
@@ -119,16 +107,15 @@ class DataDumper {
  uint32_t end_graph_stream_id_ = 0;
  bool is_end_graph_ = false;
  std::multimap<std::string, InnerInputMapping> input_map_;  // release after DavinciModel::Init
  bool load_flag_;
  uint32_t device_id_;
  uintptr_t global_step_;
  uintptr_t loop_per_iter_;
  uintptr_t loop_cond_;
  ComputeGraphPtr compute_graph_;  // release after DavinciModel::Init
  std::map<OpDescPtr, void *> ref_info_;  // release after DavinciModel::Init
  bool load_flag_ = false;
  uint32_t device_id_ = 0;
  uintptr_t global_step_ = 0;
  uintptr_t loop_per_iter_ = 0;
  uintptr_t loop_cond_ = 0;
  ComputeGraphPtr compute_graph_ = nullptr;  // release after DavinciModel::Init
  std::map<OpDescPtr, void *> ref_info_;     // release after DavinciModel::Init
  void *l1_fusion_addr_ = nullptr;
  uint32_t op_debug_task_id_ = 0;
  uint32_t op_debug_stream_id_ = 0;
  void *op_debug_addr_ = nullptr;
@@ -144,20 +131,16 @@ class DataDumper {
  Status DumpOutputWithTask(const InnerDumpInfo &inner_dump_info, aicpu::dump::Task &task);
  Status DumpInput(const InnerDumpInfo &inner_dump_info, aicpu::dump::Task &task);
  Status DumpRefInput(const DataDumper::InnerDumpInfo &inner_dump_info, aicpu::dump::Input &input, size_t i,
                       const std::string &node_name_index);
                      const std::string &node_name_index);
  Status ExecuteLoadDumpInfo(aicpu::dump::OpMappingInfo &op_mapping_info);
  void SetEndGraphIdToAicpu(uint32_t task_id, uint32_t stream_id, aicpu::dump::OpMappingInfo &op_mapping_info);
  void SetOpDebugIdToAicpu(uint32_t task_id, uint32_t stream_id, void *op_debug_addr,
                           aicpu::dump::OpMappingInfo &op_mapping_info);
  Status ExecuteUnLoadDumpInfo(aicpu::dump::OpMappingInfo &op_mapping_info);
  Status GenerateInput(aicpu::dump::Input &input,
                       const OpDesc::Vistor<GeTensorDesc> &tensor_descs,
                       const uintptr_t &addr,
                       size_t index);
  Status GenerateOutput(aicpu::dump::Output &output,
                        const OpDesc::Vistor<GeTensorDesc> &tensor_descs,
                        const uintptr_t &addr,
                        size_t index);
  Status GenerateInput(aicpu::dump::Input &input, const OpDesc::Vistor<GeTensorDesc> &tensor_descs,
                       const uintptr_t &addr, size_t index);
  Status GenerateOutput(aicpu::dump::Output &output, const OpDesc::Vistor<GeTensorDesc> &tensor_descs,
                        const uintptr_t &addr, size_t index);
  void GenerateOpBuffer(const int64_t &size, aicpu::dump::Task &task);
 };
 struct DataDumper::InnerDumpInfo {
--- a/ge/graph/load/model_manager/davinci_model.cc
+++ b/ge/graph/load/model_manager/davinci_model.cc
@@ -92,12 +92,39 @@ const uint32_t kEndOfSequence = 0x0704000a;
 const uint32_t kEndOfSequenceNew = 507005;
 const int32_t kModelAbortNormal = 0x0704000e;
 const int32_t kModelAbortNormalNew = 507024;
 const uint32_t kInteval = 2;
 const char *const kModelName = "model_name";
 const char *const kModeleId = "model_id";
 const char *const kLoadStartTime = "load_start_time";
 const char *const kLoadEndTime = "load_end_time";
 const char *const kFusionOpInfo = "fusion_op_info";
 const char *const kFusionOpName = "fusion_op_name";
 const char *const kOriginalOpNum = "origin_op_num";
 const char *const kOriginalOpName = "origin_op_name";
 const char *const kStreamId = "stream_id";
 const char *const kFusionOpMemoryInfo = "memory_info";
 const char *const kInputSize = "input_size";
 const char *const kOutputSize = "output_size";
 const char *const kWeightSize = "weight_size";
 const char *const kWorkSpaceSize = "workspace_size";
 const char *const kTotalSize = "total_size";
 const char *const kTaskCount = "task_count";
 const char *const kTaskId = "task_id";
 const char* const kRequestId = "request_id";
 const char* const kThreadId = "thread_id";
 const char* const kInputBeginTime = "input_begin_time";
 const char* const kInputEndTime = "input_end_time";
 const char* const kInferBeginTime = "infer_begin_time";
 const char* const kInferEndTime = "infer_end_time";
 const char* const kOutputBeginTime = "output_start_time";
 const char* const kOutputEndTime = "output_end_time";
 const uint32_t kStringHeadElems = 2;
 inline bool IsDataOp(const std::string &node_type) {
  return node_type == DATA_TYPE || node_type == AIPP_DATA_TYPE || node_type == ANN_DATA_TYPE;
  return (node_type == DATA_TYPE) || (node_type == AIPP_DATA_TYPE) || (node_type == ANN_DATA_TYPE);
 }
 inline bool IsTbeTask(const OpDescPtr &op_desc) {
 bool IsTbeTask(const OpDescPtr &op_desc) {
  uint32_t run_mode = static_cast<uint32_t>(domi::ImplyType::INVALID);
  if (!AttrUtils::GetInt(op_desc, ATTR_NAME_IMPLY_TYPE, run_mode)) {
    return false;
@@ -187,12 +214,12 @@ DavinciModel::~DavinciModel() {
      UnbindTaskSinkStream();
      for (size_t i = 0; i < label_list_.size(); ++i) {
        if (label_list_[i] != nullptr) {
          GE_LOGW_IF(rtLabelDestroy(label_list_[i]) != RT_ERROR_NONE, "Destroy label failed, index: %zu", i);
          GE_LOGW_IF(rtLabelDestroy(label_list_[i]) != RT_ERROR_NONE, "Destroy label failed, index:%zu.", i);
        }
      }
      for (size_t i = 0; i < stream_list_.size(); ++i) {
        GE_LOGW_IF(rtStreamDestroy(stream_list_[i]) != RT_ERROR_NONE, "Destroy stream failed, index: %zu", i);
        GE_LOGW_IF(rtStreamDestroy(stream_list_[i]) != RT_ERROR_NONE, "Destroy stream failed, index:%zu.", i);
      }
      for (size_t i = 0; i < event_list_.size(); ++i) {
@@ -205,6 +232,8 @@ DavinciModel::~DavinciModel() {
      FreeP2PMem();
      OpDebugUnRegister();
      if (l1_fusion_addr_ != nullptr) {
        GE_CHK_RT(rtFree(l1_fusion_addr_));
      }
@@ -215,8 +244,6 @@ DavinciModel::~DavinciModel() {
      }
    }
    OpDebugUnRegister();
    ReleaseTask();
    CleanTbeHandle();
@@ -251,7 +278,7 @@ void DavinciModel::UnbindHcomStream() {
    for (size_t i = 0; i < all_hccl_stream_list_.size(); i++) {
      GE_LOGW_IF(rtModelUnbindStream(rt_model_handle_, all_hccl_stream_list_[i]) != RT_ERROR_NONE,
                 "Unbind hccl stream from model failed! Index: %zu", i);
      GE_LOGW_IF(rtStreamDestroy(all_hccl_stream_list_[i]) != RT_ERROR_NONE, "Destroy hccl stream for rt_model failed!")
      GE_LOGW_IF(rtStreamDestroy(all_hccl_stream_list_[i]) != RT_ERROR_NONE, "Destroy hccl stream for rt_model failed")
    }
  }
  return;
@@ -337,7 +364,7 @@ Status DavinciModel::InitWeightMem(void *dev_ptr, void *weight_ptr, size_t weigh
 Status DavinciModel::InitFeatureMapAndP2PMem(void *dev_ptr, size_t mem_size) {
  if (is_feature_map_mem_has_inited_) {
    GELOGE(PARAM_INVALID, "call InitFeatureMapMem more than once.");
    GELOGE(PARAM_INVALID, "call InitFeatureMapMem more than once");
    return PARAM_INVALID;
  }
  is_feature_map_mem_has_inited_ = true;
@@ -391,7 +418,7 @@ Status DavinciModel::InitFeatureMapAndP2PMem(void *dev_ptr, size_t mem_size) {
 Status DavinciModel::InitVariableMem() {
  // malloc variable memory base
  var_mem_base_ = VarManager::Instance(session_id_)->GetVarMemoryBase(RT_MEMORY_HBM);
  if (TotalVarMemSize() && var_mem_base_ == nullptr) {
  if (TotalVarMemSize() && (var_mem_base_ == nullptr)) {
    Status ret = VarManager::Instance(session_id_)->MallocVarMemory(TotalVarMemSize());
    if (ret != SUCCESS) {
      GELOGE(ret, "Malloc variable memory failed.");
@@ -453,7 +480,7 @@ void DavinciModel::CheckHasHcomOp(const ComputeGraphPtr &compute_graph) {
  for (const auto &node : compute_graph->GetAllNodes()) {
    OpDescPtr op_desc = node->GetOpDesc();
    GE_IF_BOOL_EXEC(op_desc == nullptr, GELOGW("Node OpDesc is nullptr"); continue);
    GE_IF_BOOL_EXEC(op_desc == nullptr, GELOGW("Node OpDesc is nullptr."); continue);
    if (hcom_opp_types.count(op_desc->GetType()) > 0) {
      uint32_t stream_id = static_cast<uint32_t>(op_desc->GetStreamId());
      hcom_streams_.emplace(stream_id);
@@ -500,25 +527,25 @@ Status DavinciModel::DoTaskSink() {
  }
  GE_CHK_RT_RET(rtGetAicpuDeploy(&deploy_type_));
  GELOGI("do task_sink. AiCpu deploy type is: %x.", deploy_type_);
  GELOGI("Do task_sink. AiCpu deploy type is: %x.", deploy_type_);
  GE_CHK_STATUS_RET(BindModelStream(), "Bind model stream failed.");
  if (known_node_) {
    GE_CHK_STATUS_RET(MallocKnownArgs(), "Mallloc known node args failed.");
    GE_CHK_STATUS_RET(MallocKnownArgs(), "Mallloc known node's args failed");
  }
  GE_CHK_STATUS_RET(InitTaskInfo(*model_task_def.get()), "InitTaskInfo failed.");
  GE_CHK_STATUS_RET(InitTaskInfo(*model_task_def.get()), "InitTaskInfo failed");
  GE_CHK_STATUS_RET(ModelManager::GetInstance()->LaunchCustAicpuSo(), "Launch cust aicpu so failed.");
  GE_CHK_STATUS_RET(ModelManager::GetInstance()->LaunchCustAicpuSo(), "Launch cust aicpu so failed");
  GE_CHK_STATUS_RET(ModelManager::GetInstance()->CheckAicpuOpList(ge_model_), "Check aicpu op type failed.");
  GE_CHK_STATUS_RET(ModelManager::GetInstance()->CheckAicpuOpList(ge_model_), "Check aicpu op type failed");
  GE_CHK_STATUS_RET(InitEntryTask(), "InitEntryTask failed.");
  GE_CHK_STATUS_RET(InitEntryTask(), "InitEntryTask failed");
  GE_CHK_STATUS_RET(InitL1DataDumperArgs(), "InitL1DataDumperArgs failed.");
  GE_CHK_STATUS_RET(InitL1DataDumperArgs(), "InitL1DataDumperArgs failed");
  GE_CHK_STATUS_RET(DistributeTask(), "Distribute failed.");
  GE_CHK_STATUS_RET(DistributeTask(), "Distribute failed");
  GE_CHK_RT_RET(rtModelLoadComplete(rt_model_handle_));
@@ -531,7 +558,7 @@ Status DavinciModel::SetTSDevice() {
  int64_t value = 0;
  bool ret = ge::AttrUtils::GetInt(ge_model_, ATTR_MODEL_CORE_TYPE, value);
  uint32_t core_type = ret ? static_cast<uint32_t>(value) : 0;
  GELOGD("SetTSDevice: %u", core_type);
  GELOGD("SetTSDevice: %u.", core_type);
  rtError_t rt_ret = rtSetTSDevice(core_type);
  if (rt_ret != RT_ERROR_NONE) {
    GELOGE(RT_FAILED, "SetTSDevice failed, ret: 0x%X", rt_ret);
@@ -541,77 +568,21 @@ Status DavinciModel::SetTSDevice() {
 }
 Status DavinciModel::OpDebugRegister() {
  bool is_op_debug = false;
  (void)ge::AttrUtils::GetBool(ge_model_, ATTR_OP_DEBUG_FLAG, is_op_debug);
  GELOGD("The value of op debug in ge_model is %d.", is_op_debug);
  if (is_op_debug) {
    debug_reg_mutex_.lock();
    rtError_t rt_ret = rtMalloc(&op_debug_addr_, kOpDebugMemorySize, RT_MEMORY_DDR);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGE(RT_FAILED, "rtMalloc error, ret: 0x%X", rt_ret);
      return RT_ERROR_TO_GE_STATUS(rt_ret);
    }
    uint64_t debug_addrs_tmp = static_cast<uint64_t>(reinterpret_cast<uintptr_t>(op_debug_addr_));
    // For data dump, aicpu needs the pointer to pointer that save the real debug address.
    rt_ret = rtMalloc(&p2p_debug_addr_, kDebugP2pSize, RT_MEMORY_HBM);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGE(RT_FAILED, "rtMalloc error, ret: 0x%X", rt_ret);
      return RT_ERROR_TO_GE_STATUS(rt_ret);
    }
    rt_ret = rtMemcpy(p2p_debug_addr_, sizeof(uint64_t), &debug_addrs_tmp, sizeof(uint64_t), RT_MEMCPY_HOST_TO_DEVICE);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGE(RT_FAILED, "rtMemcpy to p2p_addr error: 0x%X", rt_ret);
      return RT_ERROR_TO_GE_STATUS(rt_ret);
    }
    uint32_t op_debug_mode = 0;
    (void)ge::AttrUtils::GetInt(ge_model_, ATTR_OP_DEBUG_MODE, op_debug_mode);
    GELOGD("The value of op_debug_mode in ge_model_ is %u.", op_debug_mode);
    uint32_t debug_task_id = 0;
    uint32_t debug_stream_id = 0;
    rt_ret = rtDebugRegister(rt_model_handle_, op_debug_mode, op_debug_addr_, &debug_stream_id, &debug_task_id);
    if (rt_ret != RT_ERROR_NONE) {
      GELOGE(RT_FAILED, "rtDebugRegister error, ret: 0x%X", rt_ret);
      return RT_ERROR_TO_GE_STATUS(rt_ret);
  if (GetDumpProperties().IsOpDebugOpen()) {
     uint32_t op_debug_mode = GetDumpProperties().GetOpDebugMode();
    auto ret = opdebug_register_.RegisterDebugForModel(rt_model_handle_, op_debug_mode, data_dumper_);
    if (ret != SUCCESS) {
      GELOGE(ret,"Register known shape op debug failed, ret: 0x%X",ret);
      return ret;
    }
    GELOGI("debug_task_id:%d, debug_stream_id:%u", debug_task_id, debug_stream_id);
    is_op_debug_reg_ = true;
    data_dumper_.SaveOpDebugId(debug_task_id, debug_stream_id, p2p_debug_addr_, is_op_debug);
  }
  return SUCCESS;
 }
 void DavinciModel::OpDebugUnRegister() {
  if (is_op_debug_reg_) {
    debug_reg_mutex_.unlock();
    rtError_t rt_ret = RT_ERROR_NONE;
    if (rt_model_handle_ != nullptr) {
      GELOGD("start call debug_unregister.");
      rt_ret = rtDebugUnRegister(rt_model_handle_);
      if (rt_ret != RT_ERROR_NONE) {
        GELOGW("rtDebugUnRegister failed, ret: 0x%X", rt_ret);
      }
    }
    if (op_debug_addr_ != nullptr) {
      rt_ret = rtFree(op_debug_addr_);
      if (rt_ret != RT_ERROR_NONE) {
        GELOGW("rtFree failed, ret: 0x%X", rt_ret);
      }
      op_debug_addr_ = nullptr;
    }
    if (p2p_debug_addr_ != nullptr) {
      rt_ret = rtFree(p2p_debug_addr_);
      if (rt_ret != RT_ERROR_NONE) {
        GELOGW("rtFree failed, ret: 0x%X", rt_ret);
      }
      p2p_debug_addr_ = nullptr;
    }
    opdebug_register_.UnregisterDebugForModel(rt_model_handle_);
    is_op_debug_reg_ = false;
  }
  return;
@@ -620,9 +591,9 @@ void DavinciModel::OpDebugUnRegister() {
 // initialize op sequence and call initialization function of each op respectively
 Status DavinciModel::Init(void *dev_ptr, size_t mem_size, void *weight_ptr, size_t weight_size) {
  // validating params
  GELOGI("Priority is %d", priority_);
  GELOGI("Priority is %d.", priority_);
  GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(priority_ < 0 || priority_ > 7, return PARAM_INVALID,
                                 "Priority must between 0-7, now is %d", priority_);
                                 "Priority must between 0-7, now is %d.", priority_);
  GE_CHK_BOOL_RET_STATUS(ge_model_ != nullptr, PARAM_INVALID, "GeModel is null.");
  Graph graph = ge_model_->GetGraph();
  ComputeGraphPtr compute_graph = GraphUtils::GetComputeGraph(graph);
@@ -632,7 +603,7 @@ Status DavinciModel::Init(void *dev_ptr, size_t mem_size, void *weight_ptr, size
  InitRuntimeParams();
  // RTS set aicore or vectorcore
  GE_CHK_STATUS_RET(SetTSDevice(), "SetTSDevice failed");
  GE_CHK_STATUS_RET(SetTSDevice(), "SetTSDevice failed.");
  version_ = ge_model_->GetVersion();
  name_ = ge_model_->GetName();
@@ -683,7 +654,7 @@ Status DavinciModel::Init(void *dev_ptr, size_t mem_size, void *weight_ptr, size
  runtime_param_.graph_id = compute_graph->GetGraphID();
  // op debug register
  GE_CHK_STATUS_RET(OpDebugRegister(), "OpDebugRegister failed");
  GE_CHK_STATUS_RET(OpDebugRegister(), "OpDebugRegister failed.");
  GE_TIMESTAMP_START(TransAllVarData);
  GE_CHK_STATUS_RET(TransAllVarData(compute_graph, runtime_param_.graph_id), "TransAllVarData failed.");
@@ -691,7 +662,7 @@ Status DavinciModel::Init(void *dev_ptr, size_t mem_size, void *weight_ptr, size
  GE_CHK_STATUS_RET(TransVarDataUtils::CopyVarData(compute_graph, session_id_, device_id_), "copy var data failed.");
  GE_TIMESTAMP_START(InitModelMem);
  GELOGD("Known node is %d", known_node_);
  GELOGD("Known node is %d.", known_node_);
  GE_CHK_STATUS_RET_NOLOG(InitWeightMem(dev_ptr, weight_ptr, weight_size));
  if (!known_node_) {
    GE_CHK_STATUS_RET_NOLOG(InitFeatureMapAndP2PMem(dev_ptr, mem_size));
@@ -709,10 +680,10 @@ Status DavinciModel::Init(void *dev_ptr, size_t mem_size, void *weight_ptr, size
                    (void)ge::AttrUtils::SetStr(op_desc, VAR_ATTR_VAR_IS_BROADCAST, "var_is_restore"););
  }
  GE_CHK_STATUS_RET(InitNodes(compute_graph), "Init nodes failed");
  GE_CHK_STATUS_RET(InitNodes(compute_graph), "Init nodes failed.");
  GE_TIMESTAMP_START(DoTaskSink);
  GE_CHK_STATUS_RET(DoTaskSink(), "Task sink failed");
  GE_CHK_STATUS_RET(DoTaskSink(), "Task sink failed.");
  GE_TIMESTAMP_END(DoTaskSink, "GraphLoader::DoTaskSink");
  /// In zero copy model, if a aicpu operator is connected to the first or last layer, before model execution,
@@ -739,18 +710,12 @@ Status DavinciModel::Init(void *dev_ptr, size_t mem_size, void *weight_ptr, size
    }
  }
  CREATE_STD_THREAD(shrink_id_, &DavinciModel::Shrink, this);
  Shrink();
  return SUCCESS;
 }
 Status DavinciModel::ReportProfilingData() {
  std::vector<ComputeGraphDescInfo> compute_graph_desc_info;
  Status ret = GetComputeGraphInfo(compute_graph_desc_info);
  if (ret != SUCCESS) {
    GELOGE(ret, "GetComputeGraphInfo failed.");
    return ret;
  }
  ProfilingManager::Instance().ReportProfilingData(model_id_, GetTaskDescInfo(), compute_graph_desc_info);
  ProfilingManager::Instance().ReportProfilingData(model_id_, GetTaskDescInfo());
  GE_CHK_STATUS(SinkModelProfile(), "Sink model profiler failed.");
  return SUCCESS;
@@ -1193,7 +1158,7 @@ void DavinciModel::GetAllGearsInfo(const NodePtr &node) {
      }
      if (!gear_info.empty()) {
        all_gears_info_.emplace_back(gear_info);
        GELOGD("Init all gears info from %s, gaer info is %s.", node->GetName().c_str(),
        GELOGD("Init all gears info from %s, gaer info is %s", node->GetName().c_str(),
               formats::JoinToString(gear_info).c_str());
      }
    }
@@ -1262,7 +1227,7 @@ Status DavinciModel::GetGearAndRealOutSizeInfo(const ComputeGraphPtr &graph, con
 Status DavinciModel::GetRealOutputSizeOfCase(const ComputeGraphPtr &graph, size_t input_index,
                                             const NodePtr &case_node) {
  GELOGD("Start get output size of %s, which is %zu input to netoutput.", case_node->GetName().c_str(), input_index);
  GELOGD("Start get output size of %s, which is %zu input to netoutput", case_node->GetName().c_str(), input_index);
  const auto &func_desc = case_node->GetOpDesc();
  GE_CHECK_NOTNULL(func_desc);
  std::map<vector<int32_t>, int64_t> gear_and_real_out_size_info;
@@ -1307,7 +1272,7 @@ Status DavinciModel::GetRealOutputSizeOfCase(const ComputeGraphPtr &graph, size_
 }
 Status DavinciModel::GetGearAndRealOutShapeInfo(const ComputeGraphPtr &graph, const NodePtr &node) {
  GELOGD("Start to get dynamic output dims of %s.", node->GetName().c_str());
  GELOGD("Start to get dynamic output dims of %s", node->GetName().c_str());
  merge_nodes_gear_and_real_out_shape_info_.clear();
  size_t idx = 0;
  for (const auto &in_anchor : node->GetAllInDataAnchors()) {
@@ -1321,7 +1286,7 @@ Status DavinciModel::GetGearAndRealOutShapeInfo(const ComputeGraphPtr &graph, co
    if ((peer_node->GetType() == CASE) && (op_desc->HasAttr(ATTR_INSERT_BY_MBATCH))) {
      std::vector<std::string> dynamic_output_shape_info;
      if (!AttrUtils::GetListStr(node->GetOpDesc(), ATTR_NAME_DYNAMIC_OUTPUT_DIMS, dynamic_output_shape_info)) {
        GELOGD("Can not get dynamic output dims attr from %s.", node->GetName().c_str());
        GELOGD("Can not get dynamic output dims attr from %s", node->GetName().c_str());
        return SUCCESS;
      }
      GELOGI("Dynamic output shape info is %s", formats::JoinToString(dynamic_output_shape_info).c_str());
@@ -1341,7 +1306,7 @@ Status DavinciModel::GetGearAndRealOutShapeInfo(const ComputeGraphPtr &graph, co
            output_shape.emplace_back(it[i]);
          }
          gear_and_real_out_shape_info[all_gears_info_[gear_index]] = output_shape;
          GELOGD("Get real gear index is: %zu, gear info is %s, output shape is %s.",
          GELOGD("Get real gear index is: %zu, gear info is %s, output shape is %s",
                 gear_index, formats::JoinToString(all_gears_info_[gear_index]).c_str(),
                 formats::JoinToString(output_shape).c_str());
        }
@@ -1364,7 +1329,7 @@ void DavinciModel::ParseDynamicOutShape(const std::vector<std::string> &str_info
      }
      shape.emplace_back(std::strtol(dim.c_str(), nullptr, kDecimal));
    }
    GELOGI("Shape from attr is %s.", formats::JoinToString(shape).c_str());
    GELOGI("Shape from attr is %s", formats::JoinToString(shape).c_str());
    vec_info.emplace_back(shape);
  }
 }
@@ -1407,7 +1372,7 @@ Status DavinciModel::InitLabelSet(const OpDescPtr &op_desc) {
    return INTERNAL_ERROR;
  }
  GELOGI("InitLabelSet: label[%u]=%p stream[%u]=%p.", label_index, rt_label, stream_id, stream);
  GELOGI("InitLabelSet: label[%u]=%p stream[%u]=%p", label_index, rt_label, stream_id, stream);
  label_id_indication_.insert(label_index);
  label_list_[label_index] = rt_label;
  return SUCCESS;
@@ -1810,7 +1775,7 @@ void DavinciModel::GetUserDesignateShapeOrder(std::vector<std::string> &user_inp
 ///
 Status DavinciModel::InitAippInfo(uint32_t index, const OpDescPtr &op_desc) {
  if (!op_desc->HasAttr(ATTR_NAME_AIPP)) {
    GELOGW("There is not AIPP related with index %u.", index);
    GELOGW("There is not AIPP related with index %u", index);
    return SUCCESS;
  }
@@ -1840,7 +1805,7 @@ Status DavinciModel::InitAippInfo(uint32_t index, const OpDescPtr &op_desc) {
 Status DavinciModel::GetAippInfo(uint32_t index, AippConfigInfo &aipp_info) const {
  const auto it = aipp_info_list_.find(index);
  if (it == aipp_info_list_.end()) {
    GELOGW("there is not AIPP related with index %u.", index);
    GELOGW("there is not AIPP related with index %u", index);
    return ACL_ERROR_GE_AIPP_NOT_EXIST;
  }
@@ -1850,7 +1815,7 @@ Status DavinciModel::GetAippInfo(uint32_t index, AippConfigInfo &aipp_info) cons
 Status DavinciModel::InitAippType(uint32_t index, const OpDescPtr &op_desc, const map<uint32_t, OpDescPtr> &data_list) {
  if (!op_desc->HasAttr(ATTR_DATA_RELATED_AIPP_MODE)) {
    GELOGW("There is no aipp releated info with index %u.", index);
    GELOGW("There is no aipp releated info with index %u", index);
    return SUCCESS;
  }
@@ -1895,7 +1860,7 @@ Status DavinciModel::GetAippType(uint32_t index, InputAippType &aipp_type, size_
  GE_CHK_BOOL_RET_STATUS(index < input_addrs_list_.size(), PARAM_INVALID, "Index %u is invalid", index);
  const auto it = aipp_type_list_.find(index);
  if (it == aipp_type_list_.end()) {
    GELOGW("There is no aipp releated info with index %u.", index);
    GELOGW("There is no aipp releated info with index %u", index);
    aipp_type = DATA_WITHOUT_AIPP;
    aipp_index = 0xFFFFFFFF;
    return SUCCESS;
@@ -2202,173 +2167,101 @@ Status DavinciModel::InitModelProfile() {
 }
 Status DavinciModel::SinkModelProfile() {
  // profiling plugin must be registered
  auto &prof_mgr = ProfilingManager::Instance();
  ReporterData reporter_data{};
  // report model data tag name
  std::string tag_name("model_load_info_" + std::to_string(this->Id()));
  GE_CHK_BOOL_EXEC(memcpy_s(reporter_data.tag, MSPROF_ENGINE_MAX_TAG_LEN, tag_name.c_str(), tag_name.size()) == EOK,
                   return FAILED, "Sink model tag memcpy error.");
  // Model Header
  std::string name = om_name_.empty() ? name_ : om_name_;
  size_t name_len = name.size();
  reporter_data.deviceId = device_id_;
  reporter_data.data = (unsigned char *)&name_len;
  reporter_data.dataLen = sizeof(int32_t);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u.", this->Id());
  reporter_data.data = (unsigned char *)name.c_str();
  reporter_data.dataLen = name.size();
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u.", this->Id());
  uint32_t model_id = this->Id();
  reporter_data.data = (unsigned char *)&model_id;
  reporter_data.dataLen = sizeof(uint32_t);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u.", this->Id());
  // Load Start/End Time
  int64_t start_time = this->GetLoadBeginTime();
  reporter_data.data = (unsigned char *)&start_time;
  reporter_data.dataLen = sizeof(int64_t);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u.", this->Id());
  int64_t end_time = this->GetLoadEndTime();
  reporter_data.data = (unsigned char *)&end_time;
  reporter_data.dataLen = sizeof(int64_t);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u.", this->Id());
  Json model_load_info;
  model_load_info[kModelName] = name;
  model_load_info[kModeleId] = model_id;
  model_load_info[kLoadStartTime] = start_time;
  model_load_info[kLoadEndTime] = end_time;
  // fusion op info
  using CIT = std::multimap<uint32_t, uint32_t>::const_iterator;
  using Range = std::pair<CIT, CIT>;
  for (const ProfileInfo &profile : profile_list_) {
    // op name after fusion
    Json fusion_op_info;
    string fusion_op_name = profile.fusion_info.op_name;
    int32_t fusion_op_name_len = fusion_op_name.size() == 0 ? 1 : fusion_op_name.size();
    reporter_data.data = (unsigned char *)&fusion_op_name_len;
    reporter_data.dataLen = sizeof(int32_t);
    GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                     "Reporter data fail, model id:%u.", this->Id());
    reporter_data.data = (unsigned char *)fusion_op_name.c_str();
    reporter_data.dataLen = fusion_op_name_len;
    GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                     "Reporter data fail, model id:%u.", this->Id());
    // original op name before fusion
    uint32_t op_num = profile.fusion_info.original_op_names.size();
    reporter_data.data = (unsigned char *)&op_num;
    reporter_data.dataLen = sizeof(int32_t);
    GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                     "Reporter data fail, model id:%u.", this->Id());
    vector<string> original_name;
    for (uint32_t k = 0; k < op_num; k++) {
      std::string op_name = profile.fusion_info.original_op_names[k];
      int32_t op_name_len = op_name.size() == 0 ? 1 : op_name.size();
      reporter_data.data = (unsigned char *)&op_name_len;
      reporter_data.dataLen = sizeof(int32_t);
      GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                       "Reporter data fail, model id:%u.", this->Id());
      reporter_data.data = (unsigned char *)op_name.c_str();
      reporter_data.dataLen = op_name_len;
      GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                       "Reporter data fail, model id:%u.", this->Id());
    }
    // stream id info
      original_name.emplace_back(profile.fusion_info.original_op_names[k]);
    }
    uint32_t stream_id = 0;
    auto iter = profiler_report_op_info_.find(fusion_op_name);
    if (iter != profiler_report_op_info_.end()) {
      stream_id = iter->second.second;
    }
    reporter_data.data = (unsigned char *)&stream_id;
    reporter_data.dataLen = sizeof(int32_t);
    GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                     "Reporter data fail, model id:%u.", this->Id());
    // memory info
    reporter_data.data = (unsigned char *)&profile.memory_info;
    reporter_data.dataLen = sizeof(profile.memory_info);
    GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                     "Reporter data fail, model id:%u.", this->Id());
    // task info
    reporter_data.data = (unsigned char *)&profile.task_count;
    reporter_data.dataLen = sizeof(uint32_t);
    GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                     "Reporter data fail, model id:%u.", this->Id());
    fusion_op_info[kFusionOpName] = fusion_op_name;
    fusion_op_info[kOriginalOpNum] = op_num;
    fusion_op_info[kOriginalOpName] = original_name;
    fusion_op_info[kStreamId] = stream_id;
    fusion_op_info[kFusionOpMemoryInfo][kInputSize] = profile.memory_info.input_size;
    fusion_op_info[kFusionOpMemoryInfo][kOutputSize] = profile.memory_info.output_size;
    fusion_op_info[kFusionOpMemoryInfo][kWeightSize] = profile.memory_info.weight_size;
    fusion_op_info[kFusionOpMemoryInfo][kWorkSpaceSize] = profile.memory_info.workspace_size;
    fusion_op_info[kFusionOpMemoryInfo][kTotalSize] = profile.memory_info.total_size;
    fusion_op_info[kTaskCount] = profile.task_count;
    vector<uint32_t> task_id;
    Range task_range = op_id_map_.equal_range(profile.fusion_info.op_index);
    for (CIT idx = task_range.first; idx != task_range.second; ++idx) {
      uint32_t task_id = idx->second;
      reporter_data.data = (unsigned char *)&task_id;
      reporter_data.dataLen = sizeof(uint32_t);
      GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                       "Reporter data fail, model id:%u.", this->Id());
      task_id.push_back(idx->second);
    }
    fusion_op_info[kTaskId] = task_id;
    model_load_info[kFusionOpInfo] += fusion_op_info;
  }
  std::string tag_name("model_load_info_" + std::to_string(this->Id()));
  std::string reported_data;
  try {
    reported_data = model_load_info.dump(kInteval, ' ', false, Json::error_handler_t::ignore);
  } catch (std::exception &e) {
    GELOGE(FAILED, "Failed to convert JSON to string, reason: %s.", e.what());
  } catch (...) {
    GELOGE(FAILED, "Failed to convert JSON to string.");
  }
  reported_data.append(",")
               .append("\n");
  prof_mgr.ReportData(device_id_, reported_data, tag_name);
  return SUCCESS;
 }
 Status DavinciModel::SinkTimeProfile(const InputData &current_data) {
  // profiling plugin must be registered
  auto &prof_mgr = ProfilingManager::Instance();
  ReporterData reporter_data{};
  string name = om_name_.empty() ? name_ : om_name_;
  Json model_time_info;
  model_time_info[kModelName] = name;
  model_time_info[kModeleId] = this->Id();
  model_time_info[kRequestId] = current_data.request_id;
  model_time_info[kThreadId] = mmGetTid();
  model_time_info[kInputBeginTime] = time_info_.processBeginTime;
  model_time_info[kInputEndTime] = time_info_.processEndTime;
  model_time_info[kInferBeginTime] = time_info_.inferenceBeginTime;
  model_time_info[kInferEndTime] = time_info_.inferenceEndTime;
  model_time_info[kOutputBeginTime] = time_info_.dumpBeginTime;
  model_time_info[kOutputEndTime] = time_info_.dumpEndTime;
  // report model data tag name
  std::string tag_name;
  tag_name.append("model_time_info_")
      .append(std::to_string(this->Id()))
      .append("_")
      .append(std::to_string(current_data.index));
  GE_CHK_BOOL_EXEC(memcpy_s(reporter_data.tag, MSPROF_ENGINE_MAX_TAG_LEN, tag_name.c_str(), tag_name.size()) == EOK,
                   return FAILED, "Sink model tag memcpy error.");
  // device id
  reporter_data.deviceId = device_id_;
  // Model Header
  string name;
  if (!om_name_.empty()) {
    name = om_name_;
  } else {
    name = name_;
  }
  size_t name_len = name.size();
  reporter_data.data = (unsigned char *)&name_len;
  reporter_data.dataLen = sizeof(int32_t);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u.", this->Id());
  reporter_data.data = (unsigned char *)name.c_str();
  reporter_data.dataLen = name.size();
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u.", this->Id());
  // request id
  uint64_t request_id = current_data.request_id;
  reporter_data.data = (unsigned char *)&request_id;
  reporter_data.dataLen = sizeof(uint32_t);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u, data index:%u.", this->Id(), current_data.index);
  // thread id
  int32_t thread_id = GetDataInputTid();
  reporter_data.data = (unsigned char *)&thread_id;
  reporter_data.dataLen = sizeof(int32_t);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u, data index:%u.", this->Id(), current_data.index);
  // time info
  time_info_.modelId = this->Id();
  reporter_data.data = (unsigned char *)&time_info_;
  reporter_data.dataLen = sizeof(struct timeInfo);
  GE_CHK_BOOL_EXEC(prof_mgr.CallMsprofReport(reporter_data) == 0, return FAILED,
                   "Reporter data fail, model id:%u, data index:%u.", this->Id(), current_data.index);
    .append(std::to_string(this->Id()))
    .append("_")
    .append(std::to_string(current_data.index));
  std::string reported_data;
  try {
    reported_data = model_time_info.dump(kInteval, ' ', false, Json::error_handler_t::ignore);
  } catch (std::exception &e) {
    GELOGE(FAILED, "Failed to convert JSON to string, reason: %s.", e.what());
  } catch (...) {
    GELOGE(FAILED, "Failed to convert JSON to string.");
  }
  reported_data.append(",")
               .append("\n");
  prof_mgr.ReportData(device_id_, reported_data, tag_name);
  return SUCCESS;
 }
@@ -2626,7 +2519,7 @@ Status DavinciModel::ReturnResult(uint32_t data_id, const bool rslt_flg, const b
 /// @return Status result
 ///
 Status DavinciModel::ReturnNoOutput(uint32_t data_id) {
  GELOGI("ReturnNoOutput model id:%u", model_id_);
  GELOGI("ReturnNoOutput model id:%u.", model_id_);
  GE_CHK_BOOL_EXEC(listener_ != nullptr, return PARAM_INVALID, "listener_ is null!");
  std::vector<ge::OutputTensorInfo> outputs;
@@ -2641,6 +2534,7 @@ void *DavinciModel::Run(DavinciModel *model) {
  bool seq_end_flag = false;
  uint32_t model_id = model->Id();
  uint32_t device_id = model->GetDeviceId();
  ErrorManager::GetInstance().SetErrorContext(model->GetErrorContext());
  GELOGI("Model Run thread start, model_id:%u.", model_id);
  rtError_t rt_ret = rtSetDevice(static_cast<int32_t>(device_id));
@@ -2651,6 +2545,7 @@ void *DavinciModel::Run(DavinciModel *model) {
  // DeviceReset before thread run finished!
  GE_MAKE_GUARD(not_used_var, [&] { GE_CHK_RT(rtDeviceReset(device_id)); });
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
  while (model->RunFlag()) {
    bool rslt_flg = true;
    if (model->GetDataInputer() == nullptr) {
@@ -2773,10 +2668,6 @@ Status DavinciModel::DestroyThread() {
    thread_id_.join();
  }
  if (shrink_id_.joinable()) {
    shrink_id_.join();
  }
  return SUCCESS;
 }
@@ -2807,6 +2698,7 @@ Status DavinciModel::ModelRunStart() {
  int64_t maxDumpOpNum = std::strtol(opt.c_str(), nullptr, kDecimal);
  maxDumpOpNum_ = maxDumpOpNum;
  error_context_ = ErrorManager::GetInstance().GetErrorContext();
  CREATE_STD_THREAD(thread_id_, DavinciModel::Run, this);
  GELOGI("model tread create success, model id:%u.", model_id_);
  return SUCCESS;
@@ -3069,13 +2961,15 @@ void DavinciModel::SaveProfilingTaskDescInfo(const OpDescPtr &op, const TaskInfo
    task_desc_info.model_name = name_;
  }
  task_desc_info.op_name = op->GetName();
  task_desc_info.op_type = op->GetType();
  task_desc_info.block_dim = task_def.kernel().block_dim();
  task_desc_info.task_id = task->GetTaskID();
  task_desc_info.stream_id = task->GetStreamId();
  task_desc_info.shape_type = "static";
  task_desc_info.cur_iter_num = 0;
  // task type
  task_desc_info.task_type = kTaskTypeInvalid;
  auto &prof_mgr = ProfilingManager::Instance();
  prof_mgr.GetOpInputOutputInfo(op, task_desc_info);
  auto model_task_type = static_cast<rtModelTaskType_t>(task_def.type());
  if (model_task_type == RT_MODEL_TASK_KERNEL) {
    const domi::KernelDef &kernel_def = task_def.kernel();
@@ -3107,7 +3001,6 @@ void DavinciModel::SaveProfilingTaskDescInfo(const OpDescPtr &op, const TaskInfo
      task_desc_info_.emplace_back(task_desc_info);
    }
  }
  return;
 }
 Status DavinciModel::DistributeTask() {
@@ -3332,7 +3225,7 @@ Status DavinciModel::CopyModelData(const InputData &input_data, OutputData &outp
 ///
 Status DavinciModel::UpdateIoTaskArgs(const std::map<uint32_t, ZeroCopyOffset> &data_info, bool is_input,
                                      const vector<DataBuffer> &blobs, bool is_dynamic, const string &batch_label) {
  string input_or_output = "input";
  string input_or_output;
  is_input ? input_or_output = "input" : input_or_output = "output";
  if (blobs.size() != data_info.size()) {
    GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Verify %s data num failed: model requires %zu, but user actually feeds %zu",
@@ -3342,7 +3235,8 @@ Status DavinciModel::UpdateIoTaskArgs(const std::map<uint32_t, ZeroCopyOffset> &
  for (const auto &data : data_info) {
    if (data.first >= blobs.size()) {  // check data index.
      GELOGE(ACL_ERROR_GE_PARAM_INVALID, "Verify %s data num failed: can not find No.%u data, because user only feeds %zu",
      GELOGE(ACL_ERROR_GE_PARAM_INVALID,
             "Verify %s data num failed: can not find No.%u data, because user only feeds %zu",
             input_or_output.c_str(), data.first, blobs.size());
      return ACL_ERROR_GE_PARAM_INVALID;
    }
@@ -3472,14 +3366,16 @@ Status DavinciModel::InitConstant(const OpDescPtr &op_desc) {
      elem_num = 1;
    }
    uint64_t *buff = reinterpret_cast<uint64_t *>(tensor->MutableData().data());
    GE_CHK_BOOL_RET_STATUS(ge::CheckInt64Uint32MulOverflow(elem_num, kBytes) == SUCCESS, FAILED,
                           "Shape size is invalid");
    uint64_t offset = static_cast<uint64_t>(elem_num * kBytes);
    if (ge::CheckInt64Uint32MulOverflow(elem_num, kBytes * kStringHeadElems) != SUCCESS) {
      GELOGE(FAILED, "Shape size is invalid");
      return FAILED;
    }
    uint64_t offset = elem_num * kBytes * kStringHeadElems;
    uint64_t hbm_raw_data_base_addr =
        static_cast<uint64_t>(reinterpret_cast<uintptr_t>(v_output_addr[0])) + offset;
    for (int64_t i = elem_num - 1; i >= 0; --i) {
      buff[i] = hbm_raw_data_base_addr + (buff[i] - buff[0]);
      buff[i * kStringHeadElems] = hbm_raw_data_base_addr + (buff[i * kStringHeadElems] - buff[0]);
    }
  }
  GELOGI("[IMAS]InitConstant memcpy graph_%u type[V] name[%s] output[%d] memaddr[%p] mem_size[%lu] datasize[%zu]",
@@ -4007,41 +3903,6 @@ void DavinciModel::SaveHcclFollowStream(int64_t main_stream_id, rtStream_t strea
  main_follow_stream_mapping_[main_stream_id].emplace_back(stream);
 }
 Status DavinciModel::GetComputeGraphInfo(vector<ComputeGraphDescInfo> &graph_desc_info) {
  auto &all_op_desc = data_dumper_.GetAllOpDescInfo();
  for (auto &op_desc : all_op_desc) {
    ComputeGraphDescInfo compute_graph_info;
    if (!om_name_.empty()) {
      compute_graph_info.model_name = om_name_;
    } else {
      compute_graph_info.model_name = name_;
    }
    std::vector<Format> format =  { FORMAT_NULL };
    std::vector<std::vector<int64_t>> shape = { {0} };
    std::vector<DataType> data_type = { DT_UNDEFINED };
    compute_graph_info.op_name = op_desc.op_name;
    compute_graph_info.op_type = op_desc.op_type;
    compute_graph_info.input_format = op_desc.input_format.empty() ? format : op_desc.input_format;
    compute_graph_info.input_shape = op_desc.input_shape.empty() ? shape : op_desc.input_shape;
    compute_graph_info.input_data_type = op_desc.input_data_type.empty() ? data_type : op_desc.input_data_type;
    compute_graph_info.output_format = op_desc.output_format.empty() ? format :  op_desc.output_format;
    compute_graph_info.output_shape = op_desc.output_shape.empty() ? shape : op_desc.output_shape;
    compute_graph_info.output_data_type = op_desc.output_data_type.empty() ? data_type : op_desc.output_data_type;
    uint32_t task_id = 0;
    uint32_t stream_id = 0;
    auto iter = profiler_report_op_info_.find(op_desc.op_name);
    if (iter != profiler_report_op_info_.end()) {
      task_id = iter->second.first;
      stream_id = iter->second.second;
    }
    compute_graph_info.task_id = task_id;
    compute_graph_info.stream_id = stream_id;
    graph_desc_info.emplace_back(compute_graph_info);
  }
  return SUCCESS;
 }
 void DavinciModel::SetTotalFixedAddrsSize(string tensor_name, int64_t fix_addr_size) {
  if (tensor_name_to_fixed_addr_size_.find(tensor_name) == tensor_name_to_fixed_addr_size_.end()) {
    tensor_name_to_fixed_addr_size_[tensor_name] = total_fixed_addr_size_;
@@ -4058,7 +3919,7 @@ Status DavinciModel::InitOrigInputInfo(uint32_t index, const OpDescPtr &op_desc)
  vector<string> inputs;
  if (AttrUtils::GetListStr(op_desc, ATTR_NAME_AIPP_INPUTS, inputs) && !inputs.empty()) {
    std::string input = inputs[kAippOriginInputIndex];
    GELOGI("origin input str: %s", input.c_str());
    GELOGI("origin input str: %s.", input.c_str());
    std::vector<std::string> infos = ge::StringUtils::Split(input, ':');
    if (infos.size() != kAippInfoNum) {
      GELOGE(ACL_ERROR_GE_AIPP_MODE_INVALID, "origin input str is invalid[%zu, %u].", infos.size(), kAippInfoNum);
@@ -4132,11 +3993,11 @@ Status DavinciModel::InitAippInputOutputDims(uint32_t index, const OpDescPtr &op
      ConstGeTensorDescPtr data_input_desc = op_desc->GetInputDescPtr(kDataIndex);
      int64_t data_input_size;
      (void)TensorUtils::GetSize(*(op_desc->GetInputDescPtr(kDataIndex)), data_input_size);
      GELOGD("related Data[%d]: tensor_name: %s, dim_num: %zu, tensor_size: %zu, format: %s, data_type: %s, shape: %s",
        index, op_desc->GetName().c_str(), data_input_desc->GetShape().GetDimNum(), data_input_size,
        TypeUtils::FormatToSerialString(data_input_desc->GetFormat()).c_str(),
        TypeUtils::DataTypeToSerialString(data_input_desc->GetDataType()).c_str(),
        formats::JoinToString(data_input_desc->GetShape().GetDims()).c_str());
      GELOGD("related Data[%d]: tensor_name: %s, dim_num: %zu, tensor_size: %zu, format: %s, data_type: %s, shape: %s.",
          index, op_desc->GetName().c_str(), data_input_desc->GetShape().GetDimNum(), data_input_size,
          TypeUtils::FormatToSerialString(data_input_desc->GetFormat()).c_str(),
          TypeUtils::DataTypeToSerialString(data_input_desc->GetDataType()).c_str(),
          formats::JoinToString(data_input_desc->GetShape().GetDims()).c_str());
    }
  }
--- a/ge/graph/load/model_manager/davinci_model.h
+++ b/ge/graph/load/model_manager/davinci_model.h
@@ -29,6 +29,7 @@
 #include "common/helper/om_file_helper.h"
 #include "common/opskernel/ge_task_info.h"
 #include "common/properties_manager.h"
 #include "common/dump/opdebug_register.h"
 #include "common/types.h"
 #include "framework/common/util.h"
 #include "graph/debug/ge_attr_define.h"
@@ -412,6 +413,8 @@ class DavinciModel {
  ///
  uint64_t GetSessionId() const { return session_id_; }
  const struct ErrorMessage::Context &GetErrorContext() const { return error_context_; }
  ///
  /// @ingroup ge
  /// @brief SetDeviceId
@@ -536,7 +539,7 @@ class DavinciModel {
                                   vector<InputOutputDims> &output_dims) const;
  // om file name
  void SetOmName(string om_name) { om_name_ = om_name; }
  void SetOmName(const string &om_name) { om_name_ = om_name; }
  void SetDumpProperties(const DumpProperties &dump_properties) { data_dumper_.SetDumpProperties(dump_properties); }
  const DumpProperties &GetDumpProperties() const { return data_dumper_.GetDumpProperties(); }
@@ -840,9 +843,6 @@ class DavinciModel {
  Status TransAllVarData(ComputeGraphPtr &graph, uint32_t graph_id);
  // get desc info of graph for profiling
  Status GetComputeGraphInfo(vector<ComputeGraphDescInfo> &graph_desc_info);
  void SetDataDumperArgs(const ComputeGraphPtr &graph, const map<string, OpDescPtr> &variable_by_name);
  Status InitL1DataDumperArgs();
@@ -907,7 +907,6 @@ class DavinciModel {
  vector<int64_t> output_memory_size_list_;
  thread thread_id_;
  thread shrink_id_;
  shared_ptr<ModelListener> listener_;
@@ -960,6 +959,7 @@ class DavinciModel {
  vector<uintptr_t> output_mbuf_list_;  // output mbuf created by dequeue task.
  uint64_t session_id_;
  struct ErrorMessage::Context error_context_;
  uint32_t device_id_;
@@ -985,6 +985,7 @@ class DavinciModel {
  int64_t maxDumpOpNum_;
  // for data dump
  DataDumper data_dumper_;
  OpdebugRegister opdebug_register_;
  uint64_t iterator_count_;
  bool is_l1_fusion_enable_;
  map<OpDescPtr, void *> saved_task_addrs_;  // release after DavinciModel::Init
@@ -1022,8 +1023,6 @@ class DavinciModel {
  // for op debug
  mutex debug_reg_mutex_;
  bool is_op_debug_reg_ = false;
  void *op_debug_addr_ = nullptr;
  void *p2p_debug_addr_ = nullptr;
  bool is_online_infer_dynamic_ = false;
  bool is_getnext_sink_dynamic_ = false;
  vector<int32_t> cur_dynamic_dims_;
--- a/ge/graph/load/model_manager/model_manager.cc
+++ b/ge/graph/load/model_manager/model_manager.cc
@@ -18,23 +18,15 @@
 #include <string>
 #include "mmpa/mmpa_api.h"
 #include "aicpu/aicpu_schedule/aicpu_op_type_list.h"
 #include "common/model_parser/model_parser.h"
 #include "common/dump/dump_manager.h"
 #include "common/l2_cache_optimize.h"
 #include "common/profiling/profiling_manager.h"
 #include "common/properties_manager.h"
 #include "framework/common/debug/ge_log.h"
 #include "framework/common/util.h"
 #include "graph/common/ge_call_wrapper.h"
 #include "graph/debug/ge_attr_define.h"
 #include "graph/load/model_manager/davinci_model.h"
 #include "graph/load/model_manager/davinci_model_parser.h"
 #include "model/ge_root_model.h"
 #include "graph/common/local_context.h"
 #include "graph/utils/attr_utils.h"
 #include "common/formats/utils/formats_trans_utils.h"
 #include "hybrid/hybrid_davinci_model.h"
 namespace ge {
 thread_local uint32_t device_count = 0;
@@ -55,6 +47,7 @@ const char *const kDeleteCustOp = "deleteCustOp";
 const int kTimeSpecNano = 1000000000;
 const int kTimeSpecMiro = 1000000;
 const int kOpNameMaxSize = 100;
 const uint64_t kInferSessionId = 0;
 #pragma pack(push, 1)
 struct CustAicpuSoBuf {
  uint64_t kernelSoBuf;
@@ -278,13 +271,15 @@ ge::Status ModelManager::SetDynamicSize(uint32_t model_id, const std::vector<uin
  return SUCCESS;
 }
 ge::Status ModelManager::DoLoadHybridModelOnline(uint32_t model_id, const shared_ptr<ge::GeRootModel> &ge_root_model,
 ge::Status ModelManager::DoLoadHybridModelOnline(uint32_t model_id, const string &model_name,
                                                 const shared_ptr<ge::GeRootModel> &ge_root_model,
                                                 const shared_ptr<ModelListener> &listener) {
  auto hybrid_model = hybrid::HybridDavinciModel::Create(ge_root_model);
  GE_CHECK_NOTNULL(hybrid_model);
  hybrid_model->SetListener(listener);
  hybrid_model->SetModelId(model_id);
  hybrid_model->SetDeviceId(GetContext().DeviceId());
  hybrid_model->SetModelName(model_name);
  GE_CHK_STATUS_RET(hybrid_model->Init(), "Failed to init hybrid model. model_id = %u", model_id);
  auto shared_model = std::shared_ptr<hybrid::HybridDavinciModel>(hybrid_model.release());
  InsertModel(model_id, shared_model);
@@ -304,10 +299,11 @@ Status ModelManager::LoadModelOnline(uint32_t &model_id, const shared_ptr<ge::Ge
  }
  bool is_shape_unknown = false;
  string model_name = "";
  GE_CHK_STATUS_RET(ge_root_model->CheckIsUnknownShape(is_shape_unknown), "CheckIsUnknownShape failed, model id:%u",
                    model_id);
  if (is_shape_unknown || GetContext().GetHostExecFlag()) {
    return DoLoadHybridModelOnline(model_id, ge_root_model, listener);
    return DoLoadHybridModelOnline(model_id, model_name, ge_root_model, listener);
  }
  mmTimespec timespec = mmGetTickCount();
@@ -321,7 +317,7 @@ Status ModelManager::LoadModelOnline(uint32_t &model_id, const shared_ptr<ge::Ge
  davinci_model->SetId(model_id);
  davinci_model->SetDeviceId(GetContext().DeviceId());
  const DumpProperties &dump_properties = PropertiesManager::Instance().GetDumpProperties(GetContext().SessionId());
  const DumpProperties &dump_properties = DumpManager::GetInstance().GetDumpProperties(GetContext().SessionId());
  davinci_model->SetDumpProperties(dump_properties);
  dump_properties_ = dump_properties;
@@ -1036,7 +1032,7 @@ Status ModelManager::GenSessionId(uint64_t &session_id) {
 Status ModelManager::LoadModelOffline(uint32_t &model_id, const ModelData &model, shared_ptr<ModelListener> listener,
                                      void *dev_ptr, size_t mem_size, void *weight_ptr, size_t weight_size) {
  GE_CHK_BOOL_RET_STATUS(model.key.empty() || mmAccess2(model.key.c_str(), M_F_OK) == EN_OK,
      ACL_ERROR_GE_PARAM_INVALID, "input key file path %s is invalid, %s", model.key.c_str(), strerror(errno));
      ACL_ERROR_GE_PARAM_INVALID, "Input key file path %s is invalid, %s", model.key.c_str(), strerror(errno));
  GenModelId(&model_id);
  mmTimespec timespec = mmGetTickCount();
@@ -1053,7 +1049,7 @@ Status ModelManager::LoadModelOffline(uint32_t &model_id, const ModelData &model
    GE_CHK_STATUS_RET(model_helper.GetGeRootModel()->CheckIsUnknownShape(is_shape_unknown),
                      "CheckIsUnknownShape failed, model id:%u", model_id);
    if (is_shape_unknown || GetContext().GetHostExecFlag()) {
      return DoLoadHybridModelOnline(model_id, model_helper.GetGeRootModel(), listener);
      return DoLoadHybridModelOnline(model_id, model.om_name, model_helper.GetGeRootModel(), listener);
    }
  }
@@ -1081,8 +1077,8 @@ Status ModelManager::LoadModelOffline(uint32_t &model_id, const ModelData &model
    }
    davinci_model->SetDeviceId(device_id);
    davinci_model->SetOmName(model.om_name);
    if (DumpManager::GetInstance().GetDumpProperties().IsDumpOpen()) {
      davinci_model->SetDumpProperties(DumpManager::GetInstance().GetDumpProperties());
    if (DumpManager::GetInstance().GetDumpProperties(kInferSessionId).IsDumpOpen()) {
      davinci_model->SetDumpProperties(DumpManager::GetInstance().GetDumpProperties(kInferSessionId));
    } else {
      davinci_model->SetDumpProperties(dump_properties_);
    }
@@ -1092,9 +1088,9 @@ Status ModelManager::LoadModelOffline(uint32_t &model_id, const ModelData &model
    /// Update session_id for infer in load model to avoid the same session_id.
    uint64_t new_session_id;
    ret = GenSessionId(new_session_id);
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(ret != SUCCESS, break, "Generate session_id for infer failed.");
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(ret != SUCCESS, break, "Generate session_id for inference failed.");
    ret = davinci_model->UpdateSessionId(new_session_id);
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(ret != SUCCESS, break, "Update session_id for infer failed.");
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(ret != SUCCESS, break, "Update session_id for inference failed.");
    ret = davinci_model->Init(dev_ptr, mem_size, weight_ptr, weight_size);
    GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(ret != SUCCESS, break, "DavinciInit failed.");
@@ -1403,7 +1399,7 @@ Status ModelManager::LaunchCustAicpuSo() {
 Status ModelManager::GetModelMemAndWeightSize(const ModelData &model, size_t &mem_size, size_t &weight_size) {
  uint8_t *model_data = nullptr;
  uint32_t model_len = 0;
  Status ret = DavinciModelParser::ParseModelContent(model, model_data, model_len);
  Status ret = ModelParserBase::ParseModelContent(model, model_data, model_len);
  GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(ret != SUCCESS, return ACL_ERROR_GE_PARAM_INVALID, "parse model content failed!");
  OmFileLoadHelper om_file_helper;
--- a/ge/graph/load/model_manager/model_manager.h
+++ b/ge/graph/load/model_manager/model_manager.h
@@ -73,7 +73,8 @@ class FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY ModelManager {
  ge::Status LoadModelOnline(uint32_t &model_id, const std::shared_ptr<ge::GeRootModel> &ge_root_model,
                             std::shared_ptr<ModelListener> listener);
  ge::Status DoLoadHybridModelOnline(uint32_t model_id, const shared_ptr<ge::GeRootModel> &ge_root_model,
  ge::Status DoLoadHybridModelOnline(uint32_t model_id, const string &model_name,
                                     const shared_ptr<ge::GeRootModel> &ge_root_model,
                                     const std::shared_ptr<ModelListener> &listener);
  ///
--- a/ge/graph/load/model_manager/model_utils.cc
+++ b/ge/graph/load/model_manager/model_utils.cc
@@ -387,7 +387,7 @@ Status ModelUtils::GetVarAddr(const RuntimeParam &model_param, const ConstOpDesc
        GELOGE(PARAM_INVALID, "rdma var addr is invalid, addr=%p", reinterpret_cast<uint8_t *>(offset));
        return PARAM_INVALID;
      }
      var_addr = reinterpret_cast<uint8_t *>(offset);
      var_addr = reinterpret_cast<uint8_t *>(static_cast<uintptr_t>(offset));
      break;
    case RT_MEMORY_HBM:
      VALIDATE_MEM_RANGE(op_desc, model_param.var_size, offset - model_param.logic_var_base);
--- a/ge/graph/manager/graph_caching_allocator.cc
+++ b/ge/graph/manager/graph_caching_allocator.cc
@@ -28,10 +28,9 @@ const size_t bin_ranges[kNumBins] = {kRoundBlockSize * kKByteSize,
                                     kBinSizeUnit8 * kMByteSize,
                                     kBinSizeUnit32 * kMByteSize,
                                     kBinSizeUnit128 * kMByteSize,
                                     kGByteSize,
                                     kBinSizeUnit4 * kGByteSize,
                                     kBinSizeUnit16 * kGByteSize,
                                     kBinSizeUnit26 * kGByteSize};
                                     kBinSizeUnit256 * kMByteSize,
                                     kBinSizeUnit512 * kMByteSize,
                                     kGByteSize};
 static bool BlockComparator(const Block *left, const Block *right) {
  if (left->size != right->size) {
@@ -63,7 +62,10 @@ size_t GetBinIndex(size_t size) {
 size_t GetAllocationSize(size_t size) {
  size_t index = GetBinIndex(size);
  return bin_ranges[index];
  if (bin_ranges[index] >= size) {
    return bin_ranges[index];
  }
  return kGByteSize * ((size + kGByteSize - 1) / kGByteSize);
 }
 ///
@@ -83,6 +85,15 @@ bool ShouldSplit(const Block *block, size_t size) {
  return static_cast<double>(size) <= (static_cast<double>(block->size) * kSplitThreshold);
 }
 void IncreaseCount(std::map<size_t, size_t> &count, size_t size) {
  auto it = count.find(size);
  if (it != count.end()) {
    it->second++;
  } else  {
    count.emplace(size, 1);
  }
 }
 CachingAllocator::CachingAllocator(rtMemType_t memory_type) : memory_type_(memory_type), memory_allocator_(nullptr) {
  for (uint32_t i = 0; i < kNumBins; ++i) {
    free_block_bins_[i] = nullptr;
@@ -114,11 +125,13 @@ Status CachingAllocator::Initialize(uint32_t device_id) {
 void CachingAllocator::Finalize(uint32_t device_id) {
  GELOGI("Device id %u", device_id);
  PrintStatics();
  FreeBlocks();
  FreeBlockBins();
 }
 uint8_t *CachingAllocator::Malloc(size_t size, uint8_t *org_ptr, uint32_t device_id) {
  GELOGI("Start malloc pool memory, size = %zu, device id = %u", size, device_id);
  uint8_t *ptr = nullptr;
  size = GetBlockSize(size);
  Block *block = FindFreeBlock(size, org_ptr, device_id);
@@ -202,8 +215,7 @@ BlockBin *CachingAllocator::GetBlockBin(size_t size) {
 }
 Block *CachingAllocator::FindFreeBlock(size_t size, uint8_t *org_ptr, uint32_t device_id) {
  // org_ptr - 1, try to find ptr same as org_ptr
  Block key(device_id, size, (org_ptr == nullptr ? nullptr : org_ptr - 1));
  Block key(device_id, size, org_ptr);
  BlockBin *bin = GetBlockBin(size);
  if (bin == nullptr) {
    GELOGE(ge::FAILED, "Get block bin failed size = %zu", size);
@@ -253,23 +265,28 @@ Block *CachingAllocator::SplitBlock(Block *block, size_t size, BlockBin &bin, ui
 }
 Status CachingAllocator::TryExtendCache(size_t size, uint32_t device_id) {
  GELOGI("Try to extend cache. size = %zu, device id = %u", size, device_id);
  auto memory_size = GetAllocationSize(size);
  const std::string purpose = "Memory for caching.";
  auto memory_addr = memory_allocator_->MallocMemory(purpose, memory_size, device_id);
  // try to free caches and malloc again when malloc memory failed
  if (memory_addr == nullptr) {
    FreeCachedBlocks();
    size_t free_cached_memory_size = FreeCachedBlocks();
    memory_addr = memory_allocator_->MallocMemory(purpose, memory_size, device_id);
    if (memory_addr == nullptr) {
      GELOGE(ge::FAILED, "TryExtendCache failed, no enough memory for size = %zu, device_id = %u", memory_size,
             device_id);
      return ge::FAILED;
    }
    GELOGT(TRACE_RUNNING, "Try to free cached memory size:%zu and malloc memory size:%zu success.",
           free_cached_memory_size, memory_size);
  }
  if (AddToBlockBin(memory_addr, memory_size, device_id) != ge::SUCCESS) {
    (void)memory_allocator_->FreeMemory(memory_addr);
    return ge::FAILED;
  }
  PrintStatics();
  return ge::SUCCESS;
 }
@@ -290,13 +307,15 @@ Status CachingAllocator::AddToBlockBin(uint8_t *ptr, size_t size, uint32_t devic
  block->size = size;
  std::lock_guard<std::recursive_mutex> lock(mutex_);
  IncreaseCount(malloced_memory_, block->size);
  bin->insert(block);
  return ge::SUCCESS;
 }
 void CachingAllocator::FreeCachedBlocks() {
 size_t CachingAllocator::FreeCachedBlocks() {
  GELOGI("Free cached blocks");
  std::lock_guard<std::recursive_mutex> lock(mutex_);
  size_t free_cached_memory_size = 0;
  for (uint32_t i = 0; i < kNumBins; ++i) {
    auto pool = free_block_bins_[i];
    if (pool == nullptr) {
@@ -307,6 +326,14 @@ void CachingAllocator::FreeCachedBlocks() {
      // free block memory that has not been split
      if ((block != nullptr) && (block->ptr != nullptr) && (block->prev == nullptr) && (block->next == nullptr) &&
          (memory_allocator_->FreeMemory(block->ptr) == ge::SUCCESS)) {
        auto itcount = malloced_memory_.find(block->size);
        free_cached_memory_size += block->size;
        if (itcount != malloced_memory_.end()) {
          itcount->second--;
          if (itcount->second == 0) {
            malloced_memory_.erase(itcount);
          }
        }
        pool->erase(it++);
        delete block;
        continue;
@@ -314,6 +341,7 @@ void CachingAllocator::FreeCachedBlocks() {
      ++it;
    }
  }
  return free_cached_memory_size;
 }
 void CachingAllocator::FreeBlocks() {
@@ -324,8 +352,7 @@ void CachingAllocator::FreeBlocks() {
    FreeBlock(it.second);
  }
  allocated_blocks_.clear();
  FreeCachedBlocks();
  (void) FreeCachedBlocks();
 }
 void CachingAllocator::FreeBlockBins() {
@@ -338,4 +365,60 @@ void CachingAllocator::FreeBlockBins() {
    }
  }
 }
 void PrintCount(std::map<size_t, size_t> &count, const std::string &name, size_t total_size, size_t total_count) {
  GELOGI("%6s total[size:%10zu count:%10zu]", name.c_str(), total_size, total_count);
  for (auto &it : count) {
    GELOGI("    |- block[size:%10zu count:%10zu]", it.first, it.second);
  }
 }
 void CachingAllocator::PrintStatics() {
  if (!IsLogEnable(GE_MODULE_NAME, DLOG_INFO)) {
    return;
  }
  size_t total_using_size = 0;
  size_t total_using_count = 0;
  size_t total_free_size = 0;
  size_t total_free_count = 0;
  size_t total_malloc_size = 0;
  size_t total_malloc_count = 0;
  std::map<size_t, size_t> using_block;
  std::map<size_t, size_t> free_block;
  std::map<size_t, size_t> malloc_block;
  do {
    std::lock_guard<std::recursive_mutex> lock(mutex_);
    for (uint32_t i = 0; i < kNumBins; ++i) {
      auto pool = free_block_bins_[i];
      if (pool == nullptr) {
        continue;
      }
      for (auto it = pool->begin(); it != pool->end(); ++it) {
        if ((*it) != nullptr) {
          total_free_size += (*it)->size;
          IncreaseCount(free_block, (*it)->size);
          total_free_count++;
        }
      }
    }
    for (auto &it : allocated_blocks_) {
      if (it.second != nullptr) {
        total_using_size += it.second->size;
        IncreaseCount(using_block, it.second->size);
        total_using_count++;
      }
    }
    for (auto &it : malloced_memory_) {
      total_malloc_size += it.first * it.second;
      total_malloc_count += it.second;
      malloc_block[it.first] = it.second;
    }
  } while (0);
  PrintCount(malloc_block, "Malloc", total_malloc_size, total_malloc_count);
  PrintCount(using_block, "Using", total_using_size, total_using_count);
  PrintCount(free_block, "Free", total_free_size, total_free_count);
 }
 }  // namespace ge
--- a/ge/graph/manager/graph_caching_allocator.h
+++ b/ge/graph/manager/graph_caching_allocator.h
@@ -36,17 +36,17 @@ namespace ge {
 constexpr size_t kRoundBlockSize = 512;         // all block sizes are rounded to at least 512 bytes
 constexpr size_t kBinSizeUnit4 = 4;
 constexpr size_t kBinSizeUnit8 = 8;
 constexpr size_t kBinSizeUnit16 = 16;
 constexpr size_t kBinSizeUnit26 = 26;
 constexpr size_t kBinSizeUnit32 = 32;
 constexpr size_t kBinSizeUnit128 = 128;
 constexpr size_t kBinSizeUnit256 = 256;
 constexpr size_t kBinSizeUnit512 = 512;
 constexpr double kSplitThreshold = 0.75;         // split when malloc size <= small block size * kSpliThreshold
 constexpr double kSplitThreshold = 0.5;         // split when malloc size <= small block size * kSpliThreshold
 constexpr size_t kKByteSize = 1024;
 constexpr size_t kMByteSize = 1048576;   // 1024 * 1024
 constexpr size_t kGByteSize = 1073741824;   // 1024 * 1024 * 1024
 static const uint32_t kNumBins = 8;
 static const uint32_t kNumBins = 7;
 class MemoryAllocator;
@@ -143,9 +143,9 @@ class CachingAllocator {
  ///
  /// @ingroup ge_graph
  /// @brief free all cached blocks to right bin and release the memory when memory is not enough
  /// @return void
  /// @return free cached memory size
  ///
  void FreeCachedBlocks();
  size_t FreeCachedBlocks();
  ///
  /// @ingroup ge_graph
@@ -182,6 +182,13 @@ class CachingAllocator {
  ///
  Block *SplitBlock(Block *block, size_t size, BlockBin &bin, uint32_t device_id);
  ///
  /// @ingroup ge_graph
  /// @brief print the memory info in pool
  /// @return void
  ///
  void PrintStatics();
 private:
  rtMemType_t memory_type_;
@@ -196,6 +203,9 @@ class CachingAllocator {
  // block bins by different block size
  BlockBin *free_block_bins_[kNumBins];
  // malloced memorys from device
  std::map<size_t, size_t> malloced_memory_;
 };
 }  // namespace ge
 #endif  // GE_GRAPH_MANAGER_GRAPH_CACHING_ALLOCATOR_H_
--- a/ge/graph/manager/graph_manager.cc
+++ b/ge/graph/manager/graph_manager.cc
@@ -26,6 +26,7 @@
 #include "common/math/math_util.h"
 #include "common/thread_pool.h"
 #include "common/dump/dump_manager.h"
 #include "analyzer/analyzer.h"
 #include "graph/common/ge_call_wrapper.h"
 #include "graph/common/local_context.h"
@@ -141,7 +142,7 @@ ge::Status CheckFpCeilingMode() {
    GELOGI("The parameter fp_ceiling_mode is set to %s.", mode.c_str());
    return ge::SUCCESS;
  }
  GELOGW("The parameter fp_ceiling_mode is not set.");
  GELOGW("The parameter fp_ceiling_mode is not set");
  return ge::SUCCESS;
 }
 }  // namespace
@@ -154,6 +155,7 @@ GraphManager::GraphManager()
 }
 Status GraphManager::Initialize(const std::map<string, string> &options) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kInitialize, ErrorMessage::kOther);
  if (init_flag_) {
    GELOGW("[Initialize] GraphManager already initialized.");
    return SUCCESS;
@@ -293,7 +295,7 @@ Status GraphManager::InitDynamicParams(ComputeGraphPtr &compute_graph) {
      return FAILED;
    }
    if ((op_desc->GetType() == DATA) || (op_type == kGetNextName)) {
      GELOGI("Need to process multi batch for compute graph.");
      GELOGI("Need to process multi batch for compute graph. op_type:%s.", op_desc->GetType().c_str());
      GetLocalOmgContext().need_multi_batch = true;
      break;
    }
@@ -542,6 +544,7 @@ Status GraphManager::OptimizeSubGraphWithMultiThreads(ComputeGraphPtr compute_gr
    std::future<Status> f = executor.commit(GraphManager::ProcessSubGraphWithMultiThreads, this,
                                            compute_graph->GetGraphID(), subgraph,
                                            compute_graph->GetName(), session_id,
                                            ErrorManager::GetInstance().GetErrorContext(),
                                            GetThreadLocalContext());
    if (!f.valid()) {
      GELOGE(FAILED, "Future is invalid");
@@ -558,6 +561,7 @@ Status GraphManager::OptimizeSubGraphWithMultiThreads(ComputeGraphPtr compute_gr
      std::future<Status> f = executor.commit(GraphManager::ProcessSubGraphWithMultiThreads, this,
                                              compute_graph->GetGraphID(), subgraph,
                                              compute_graph->GetName(), session_id,
                                              ErrorManager::GetInstance().GetErrorContext(),
                                              GetThreadLocalContext());
      if (!f.valid()) {
        GELOGE(FAILED, "Future is invalid");
@@ -663,6 +667,7 @@ Status GraphManager::SetSubgraph(uint64_t session_id, ComputeGraphPtr compute_gr
 Status GraphManager::PreRunOptimizeOriginalGraph(const GraphNodePtr &graph_node, const std::vector<GeTensor> &inputs,
                                                 ge::ComputeGraphPtr &compute_graph, uint64_t session_id) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kPrepareOptimize);
  GE_CHECK_NOTNULL(graph_node);
  GE_CHECK_NOTNULL(compute_graph);
@@ -671,8 +676,10 @@ Status GraphManager::PreRunOptimizeOriginalGraph(const GraphNodePtr &graph_node,
  GM_RUN_AND_DUMP_PERF("HandleSummaryOp", stages.optimizer.HandleSummaryOp, compute_graph);
  GM_RUN_AND_DUMP_PERF("Prepare", stages.preparer.PrepareDynShape, graph_node, inputs, compute_graph,
                       session_id);
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOriginOptimize);
  GM_RUN_AND_DUMP_PERF("OptimizeOriginalGraph", stages.optimizer.OptimizeOriginalGraph, compute_graph);
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kPrepareOptimize);
  GM_RUN_AND_DUMP_PERF("PrepareRunningFormatRefiner", stages.preparer.PrepareRunningFormatRefiner);
  GM_RUN_AND_DUMP_PERF("RefineRunningFormat", stages.optimizer.OptimizeOriginalGraphJudgeInsert, compute_graph);
  GM_RUN_AND_DUMP_PERF("SubexpressionMigration", SubexpressionMigration, compute_graph);
@@ -715,6 +722,7 @@ Status GraphManager::PreRunAfterOptimizeSubGraph(const GraphNodePtr &graph_node,
  GE_CHECK_NOTNULL(graph_node);
  GE_CHECK_NOTNULL(compute_graph);
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kMergeGraphOptimize);
  CompilerStages &stages = GetCompilerStages(graph_node->GetGraphId());
  GM_RUN_AND_DUMP_PERF("OptimizeWholeGraph", stages.optimizer.OptimizeWholeGraph, compute_graph);
  GM_RUN_AND_DUMP_PERF("Optimize2", OptimizeStage2, compute_graph);
@@ -734,8 +742,8 @@ Status GraphManager::PreRunAfterOptimizeSubGraph(const GraphNodePtr &graph_node,
 }
 Status GraphManager::SetRtContext(rtContext_t rt_context, rtCtxMode_t mode, uint64_t session_id, uint32_t graph_id) {
  GELOGD("set rt_context, session id: %lu, graph id: %u, mode %d, device id:%u.", session_id, graph_id,
         static_cast<int>(mode), ge::GetContext().DeviceId());
  GELOGD("set rt_context: session id: %lu, graph id: %u, mode %d, device id:%u.",
         session_id, graph_id, static_cast<int>(mode), ge::GetContext().DeviceId());
  rtError_t rt_ret = rtCtxCreate(&rt_context, mode, ge::GetContext().DeviceId());
  if (rt_ret != RT_ERROR_NONE) {
@@ -776,7 +784,7 @@ Status GraphManager::PreRun(const GraphNodePtr &graph_node, const std::vector<Ge
  GE_CHK_STATUS_RET(analyzer_instance->BuildJsonObject(session_id, compute_graph->GetGraphID()),
                    "BuildJsonObject Failed")
  GEEVENT("PreRun start, graph node size %zu, session id %lu, graph id %u, graph name %s",
  GEEVENT("PreRun start: graph node size %zu, session id %lu, graph id %u, graph name %s",
          compute_graph->GetDirectNodesSize(), session_id, compute_graph->GetGraphID(),
          compute_graph->GetName().c_str());
  GE_DUMP(compute_graph, "PreRunBegin");
@@ -797,11 +805,12 @@ Status GraphManager::PreRun(const GraphNodePtr &graph_node, const std::vector<Ge
  if (run_optimize_original_graph) {
    Status ret = PreRunOptimizeOriginalGraph(graph_node, inputs, compute_graph, session_id);
    if (ret != SUCCESS) {
      GELOGE(ret, "Run PreRunOptimizeOriginalGraph failed for graph:%s.", compute_graph->GetName().c_str());
      GELOGE(ret, "Run PreRunOptimizeOriginalGraph failed for graph:%s", compute_graph->GetName().c_str());
      return ret;
    }
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kPrepareOptimize);
  ret = PreRunOptimizeSubGraph(graph_node, compute_graph, session_id);
  if (ret != SUCCESS) {
    GELOGE(ret, "Run PreRunOptimizeSubGraph failed for graph:%s.", compute_graph->GetName().c_str());
@@ -823,6 +832,7 @@ Status GraphManager::PreRun(const GraphNodePtr &graph_node, const std::vector<Ge
    }
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  // when set incre build, save om model and var manager
  GeModelPtr ge_model = nullptr;
  auto save_ret = SaveCacheAfterBuild(graph_node->GetGraphId(), compute_graph, ge_model);
@@ -854,6 +864,7 @@ Status GraphManager::StartForRunGraph(const GraphNodePtr &graph_node, const std:
  // it will not execute graph prreprocess, optimize, parition, build if the graph has built successful.
  Status ret = SUCCESS;
  if (IsGraphNeedBuild(graph_node)) {
    ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
    if (graph_node->GetBuildFlag()) {
      GELOGE(PARAM_INVALID,
             "The graph %u need to re-build, you should remove it from GE "
@@ -869,10 +880,11 @@ Status GraphManager::StartForRunGraph(const GraphNodePtr &graph_node, const std:
      // release rts generate context
      RtContextUtil::GetInstance().DestroyRtContexts(session_id, graph_node->GetGraphId());
      if (ret != SUCCESS) {
        GELOGE(ret, "PreRun Failed.");
        GELOGE(ret, "PreRun Failed. graph_id:%u.", graph_node->GetGraphId());
        return ret;
      }
    }
    ErrorManager::GetInstance().SetStage(ErrorMessage::kModelLoad, ErrorMessage::kModelLoad);
    if (!graph_node->IsAsync()) {
      ret = LoadGraph(ge_root_model, graph_node);
    } else {
@@ -885,6 +897,7 @@ Status GraphManager::StartForRunGraph(const GraphNodePtr &graph_node, const std:
    graph_node->SetBuildFlag(true);
    var_acc_ctrl_.SetGraphBuildEnd(graph_node->GetGraphId());
  } else if (!graph_node->GetLoadFlag()) {
    ErrorManager::GetInstance().SetStage(ErrorMessage::kModelLoad, ErrorMessage::kModelLoad);
    GeRootModelPtr ge_root_model_ptr = graph_node->GetGeRootModel();
    if (!graph_node->IsAsync()) {
      ret = LoadGraph(ge_root_model_ptr, graph_node);
@@ -1042,6 +1055,7 @@ Status GraphManager::InnerRunGraph(GraphNodePtr &graph_node, const GraphId &grap
 Status GraphManager::RunGraph(const GraphId &graph_id, const std::vector<GeTensor> &inputs,
                              std::vector<GeTensor> &outputs, uint64_t session_id) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  std::lock_guard<std::mutex> lock(run_mutex_);
  GELOGI("[RunGraph] start to run graph, graph_id = %u, is_train_graph: %d", graph_id, GetTrainFlag());
@@ -1094,6 +1108,7 @@ Status GraphManager::RunGraph(const GraphId &graph_id, const std::vector<GeTenso
    return ret;
  }
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
  // excute graph
  ret = InnerRunGraph(graph_node, graph_id, inputs, outputs);
  if (ret != SUCCESS) {
@@ -1209,7 +1224,8 @@ Status GraphManager::BuildGraphForUnregisteredOp(const GraphId &graph_id, const
 Status GraphManager::BuildGraph(const GraphId &graph_id, const std::vector<GeTensor> &inputs,
                                GeRootModelPtr &ge_root_model, uint64_t session_id, bool async) {
  GELOGD("[BuildGraph] start to build graph, graph_id=%u.", graph_id);
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  GELOGD("[BuildGraph] start to build graph, graph_id:%u", graph_id);
  if (inputs.empty()) {
    GELOGW("[BuildGraph] BuildGraph warning: empty GeTensor inputs");
  }
@@ -1241,7 +1257,7 @@ Status GraphManager::BuildGraph(const GraphId &graph_id, const std::vector<GeTen
  ret = StartForRunGraph(graph_node, inputs, ge_root_model, session_id);
  graph_node->SetRunFlag(false);
  if (ret != SUCCESS) {
    GELOGE(GE_GRAPH_PRERUN_FAILED, "[BuildGraph] StartForRunGraph failed!");
    GELOGE(GE_GRAPH_PRERUN_FAILED, "[BuildGraph] StartForRunGraph failed! graph_id:%u.", graph_id);
    return GE_GRAPH_PRERUN_FAILED;
  }
@@ -1495,7 +1511,7 @@ Status GraphManager::ParseOptions(const std::map<std::string, std::string> &opti
  ParseOption(options, INPUT_SHAPE, options_.input_shape);
  ParseOption(options, kDynamicDims, options_.dynamic_dims);
  ParseOption(options, DYNAMIC_NODE_TYPE, options_.dynamic_node_type);
  GELOGD("Dynamic dims params: input shape is %s, dynamic dims is %s, dynamic node type is %d.",
  GELOGD("Dynamic dims params: input shape is %s, dynamic dims is %s, dynamic node type is %d",
         options_.input_shape.c_str(), options_.dynamic_dims.c_str(), options_.dynamic_node_type);
  // Set Build model and step
@@ -1508,7 +1524,7 @@ Status GraphManager::ParseOptions(const std::map<std::string, std::string> &opti
 Status GraphManager::ParseTrainGraphFlag(bool &options, bool &option) {
  std::shared_ptr<GELib> ge_instance_ptr = ge::GELib::GetInstance();
  if (ge_instance_ptr == nullptr) {
    GELOGW("[Initialize] set train_graph_flag_ to 0 when GE is not initialized or finalized.");
    GELOGW("[Initialize] set train_graph_flag to 0 when GE is not initialized or finalized");
    option = false;
  } else if (!ge_instance_ptr->isTrainMode()) {
    option = false;
@@ -1525,7 +1541,8 @@ Status GraphManager::ParseTrainGraphFlag(bool &options, bool &option) {
 bool GraphManager::IsPerfLevelInvalid(int32_t perf_level) {
  return ((perf_level != static_cast<int32_t>(GEN_TASK_WITHOUT_L2FUSION)) &&
          (perf_level != static_cast<int32_t>(GEN_TASK_WITHOUT_FUSION)) && (perf_level != -1));
          (perf_level != static_cast<int32_t>(GEN_TASK_WITHOUT_FUSION)) &&
          (perf_level != -1));
 }
 void GraphManager::ParseOption(const std::map<std::string, std::string> &options, const std::string &key,
@@ -2254,9 +2271,8 @@ Status GraphManager::OptimizeStage2(ge::ComputeGraphPtr &compute_graph) {
  GE_CHK_STATUS_RET(after_merge_passes.AddPass("OptimizeStage2::AfterMergePasses::LinkGenMaskNodesPass",
                                               new (std::nothrow)
                                                   LinkGenMaskNodesPass(options_.stream_max_parallel_num)));
  GE_CHK_STATUS_RET(
    after_merge_passes.AddPass("OptimizeStage2::HcclContinuousMemcpyPass",
                                 new (std::nothrow) HcclContinuousMemcpyPass));
  GE_CHK_STATUS_RET(after_merge_passes.AddPass("OptimizeStage2::HcclContinuousMemcpyPass",
                                               new (std::nothrow) HcclContinuousMemcpyPass));
  GE_TIMESTAMP_START(after_merge_passes);
  auto ret = after_merge_passes.Run(compute_graph);
@@ -2509,8 +2525,10 @@ Status GraphManager::ProcessSubGraphWithMultiThreads(GraphManager *graph_manager
                                                     const SubGraphInfoPtr &sub_graph_info_ptr,
                                                     const std::string &root_graph_name,
                                                     uint64_t session_id,
                                                     const struct ErrorMessage::Context &error_context,
                                                     const GEThreadLocalContext &ge_context) {
  if (sub_graph_info_ptr != nullptr && graph_manager != nullptr) {
    ErrorManager::GetInstance().SetErrorContext(error_context);
    GetContext().SetSessionId(session_id);
    GetThreadLocalContext() = ge_context;
    graph_manager->UpdateLocalOmgContext(root_graph_id);
@@ -2555,9 +2573,12 @@ Status GraphManager::ProcessSubGraphWithMultiThreads(GraphManager *graph_manager
 // run graph async on session
 Status GraphManager::RunGraphAsync(const GraphId &graph_id, const std::vector<ge::InputTensorInfo> &inputs,
                                   uint64_t session_id, RunAsyncCallback callback) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
  GELOGI("[GraphManager] Start to run graph async, graph_id=%u, inputsSize=%zu.", graph_id, inputs.size());
  bool ret = prerun_args_q_.Push(PreRunArgs({graph_id, inputs, session_id, GetThreadLocalContext(), callback}));
  bool ret = prerun_args_q_.Push(PreRunArgs({graph_id, inputs, session_id,
    ErrorManager::GetInstance().GetErrorContext(),
    GetThreadLocalContext(), callback}));
  if (!ret) {
    GELOGE(FAILED, "[GraphManager] Run graph async failed, graph_id=%u.", graph_id);
    return FAILED;
@@ -2644,6 +2665,8 @@ void GraphManager::PreRunThread(GraphManager *graph_manager) {
    GELOGI("A new loop start.");
    ErrorManager::GetInstance().SetErrorContext(args.error_context);
    ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
    GetContext().SetSessionId(args.session_id);
    GetThreadLocalContext() = args.context;
    graph_manager->UpdateLocalOmgContext(args.graph_id);
@@ -2725,8 +2748,8 @@ void GraphManager::PreRunThread(GraphManager *graph_manager) {
      ge_root_model = graph_node->GetGeRootModel();
    }
    graph_manager->run_args_q_.Push(RunArgs( { graph_node, args.graph_id, args.session_id, args.input_tensor,
        ge_root_model, GetThreadLocalContext(), args.callback }));
    graph_manager->run_args_q_.Push(RunArgs( { graph_node, args.graph_id, args.session_id, args.error_context,
        args.input_tensor, ge_root_model, GetThreadLocalContext(), args.callback }));
    GELOGI("Loop end.");
  }
 }
@@ -2812,6 +2835,7 @@ Status GraphManager::ParseInputsDims(const std::vector<InputTensorInfo> &input_t
 }
 void GraphManager::RunThread(GraphManager *graph_manager) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
  if (prctl(PR_SET_NAME, ("GE_Run")) != 0) {
    GELOGW("Set thread name failed.");
  }
@@ -2825,6 +2849,7 @@ void GraphManager::RunThread(GraphManager *graph_manager) {
    GELOGI("A new loop start.");
    ErrorManager::GetInstance().SetErrorContext(args.error_context);
    GetContext().SetSessionId(args.session_id);
    GetThreadLocalContext() = args.context;
    graph_manager->UpdateLocalOmgContext(args.graph_id);
@@ -2842,6 +2867,7 @@ void GraphManager::RunThread(GraphManager *graph_manager) {
    }
    if (!args.graph_node->GetLoadFlag()) {
      ErrorManager::GetInstance().SetStage(ErrorMessage::kModelLoad, ErrorMessage::kModelLoad);
      ret = graph_manager->LoadGraphAsync(args.ge_root_model, args.graph_node);
      if (ret != SUCCESS || args.ge_root_model == nullptr) {
        StopQueue(graph_manager);
@@ -2854,6 +2880,7 @@ void GraphManager::RunThread(GraphManager *graph_manager) {
             args.ge_root_model->GetModelId());
    }
    ErrorManager::GetInstance().SetStage(ErrorMessage::kModelExecute, ErrorMessage::kModelExecute);
    if (graph_manager->GetTrainFlag()) {
      ret = graph_manager->graph_executor_.SetGraphContext(graph_manager->GetGraphContext());
      if (ret != SUCCESS) {
@@ -3063,6 +3090,15 @@ Status GraphManager::OptimizeSubgraph(const GraphNodePtr &graph_node, ComputeGra
    sub_graph->SetSessionID(session_id);
    sub_graph->SetGraphID(graph_node->GetGraphId());
  }
  bool off_superkernel = false;
  if (AttrUtils::GetBool(compute_graph, ATTR_NAME_OFF_SUPERKERNEL_ATTR, off_superkernel)) {
    GELOGI("Compute graph %s get superkernel flag %d.", compute_graph->GetName().c_str(), off_superkernel);
    if (!AttrUtils::SetBool(merged_compute_graph, ATTR_NAME_OFF_SUPERKERNEL_ATTR, off_superkernel)) {
      GELOGE(FAILED, "Compute graph %s set superkernel flag %d failed", merged_compute_graph->GetName().c_str(),
             off_superkernel);
      return FAILED;
    }
  }
  GE_TIMESTAMP_EVENT_END(MergeSubgraph, "OptimizeSubgraph::MergeSubGraph");
  GE_DUMP(merged_compute_graph, "mergedComputeGraph");
  compute_graph = merged_compute_graph;
@@ -3101,6 +3137,7 @@ Status GraphManager::ConvertGraphToFile(ComputeGraphPtr &compute_graph, GraphPar
 Status GraphManager::Build(const GraphNodePtr &graph_node, ComputeGraphPtr &compute_graph,
                           GeRootModelPtr &ge_root_model, uint64_t session_id) {
  ErrorManager::GetInstance().SetStage(ErrorMessage::kModelCompile, ErrorMessage::kOther);
  // build
  if (compute_graph != nullptr) {
    std::string graph_name = compute_graph->GetName();
@@ -3116,7 +3153,7 @@ Status GraphManager::Build(const GraphNodePtr &graph_node, ComputeGraphPtr &comp
  }
  bool is_always_dump = false;
  if (!PropertiesManager::Instance().GetDumpProperties(session_id).GetDumpPath().empty()) {
  if (!DumpManager::GetInstance().GetDumpProperties(session_id).GetDumpPath().empty()) {
    is_always_dump = true;
  }
@@ -3168,7 +3205,7 @@ Status GraphManager::SaveVariables(const Graph &graph, const std::vector<std::st
        return FAILED;
      } else {
        auto var_tensor = var_results[var_name].GetTensorDesc();
        var_tensor.SetName(var_name);
        var_tensor.SetName(var_name.c_str());
        var_results[var_name].SetTensorDesc(var_tensor);
        var_values.emplace_back(var_results[var_name]);
      }
@@ -3177,7 +3214,7 @@ Status GraphManager::SaveVariables(const Graph &graph, const std::vector<std::st
    for (auto iter = var_results.begin(); iter != var_results.end(); ++iter) {
      string var_name = iter->first;
      auto var_tensor = iter->second.GetTensorDesc();
      var_tensor.SetName(var_name);
      var_tensor.SetName(var_name.c_str());
      iter->second.SetTensorDesc(var_tensor);
      var_values.emplace_back(iter->second);
    }
--- a/ge/graph/manager/graph_manager.h
+++ b/ge/graph/manager/graph_manager.h
@@ -196,6 +196,7 @@ class GraphManager {
    GraphId graph_id;
    std::vector<ge::InputTensorInfo> input_tensor;
    uint64_t session_id;
    struct ErrorMessage::Context error_context;
    GEThreadLocalContext context;
    RunAsyncCallback callback;
  };
@@ -204,6 +205,7 @@ class GraphManager {
    GraphNodePtr graph_node;
    GraphId graph_id;
    uint64_t session_id;
    struct ErrorMessage::Context error_context;
    std::vector<ge::InputTensorInfo> input_tensor;
    GeRootModelPtr ge_root_model;
    GEThreadLocalContext context;
@@ -221,6 +223,7 @@ class GraphManager {
                                                const SubGraphInfoPtr &sub_graph_info_ptr,
                                                const std::string &root_graph_name,
                                                uint64_t session_id,
                                                const struct ErrorMessage::Context &error_context,
                                                const GEThreadLocalContext &ge_context);
  Status ParseInputsDims(const std::vector<InputTensorInfo> &input_tensor);
  void ParseInputsDimsForData(const std::vector<InputTensorInfo> &input_tensor);
--- a/ge/graph/manager/graph_mem_allocator.h
+++ b/ge/graph/manager/graph_mem_allocator.h
@@ -26,6 +26,7 @@
 #include "framework/common/debug/ge_log.h"
 #include "framework/common/ge_inner_error_codes.h"
 #include "graph/manager/host_mem_allocator.h"
 #include "graph/node.h"
 #include "runtime/mem.h"
@@ -139,7 +140,6 @@ class MemoryAllocator {
 using MemoryAllocatorPtr = std::shared_ptr<MemoryAllocator>;
 class CachingAllocator;
 class RdmaPoolAllocator;
 class HostMemAllocator;
 class MemManager {
 public:
  MemManager();
--- a/ge/graph/optimize/common/params.h
+++ b/ge/graph/optimize/common/params.h
@@ -55,7 +55,7 @@ class Params : public Singleton<Params> {
  Params() : target_("MINI") {}
  string target_;
  uint8_t target_8bit_ = 0;
  uint8_t target_8bit_ = TARGET_TYPE_MINI_8BIT;
 };
 }  // namespace ge
--- a/ge/graph/partition/dynamic_shape_partition.cc
+++ b/ge/graph/partition/dynamic_shape_partition.cc
@@ -601,6 +601,8 @@ std::string Cluster::DebugString() const {
    case KNOWN_SHAPE:
      ss << "KNOW";
      break;
    default:
      break;
  }
  ss << "[" << id_ << "](size:" << nodes_.size() << ")";
  ss << "(" << min_ << "," << max_ << ")(";
--- a/ge/graph/passes/assign_remove_pass.cc
+++ b/ge/graph/passes/assign_remove_pass.cc
@@ -24,9 +24,9 @@ namespace {
 constexpr uint32_t kValidInputNodeOutputNum = 1;
 constexpr int32_t kAssignRefInputIndex = 0;
 constexpr int32_t kAssignValueInputIndex = 1;
 static const std::set<std::string> kNoTaskNodeTypes = { ge::DATA, ge::ANN_DATA, ge::AIPPDATA,
                                                        ge::CONSTANT, ge::CONSTANTOP,
                                                        ge::VARIABLE, ge::VARIABLEV2 };
 const std::set<std::string> kNoTaskNodeTypes = { ge::DATA, ge::ANN_DATA, ge::AIPPDATA,
                                                 ge::CONSTANT, ge::CONSTANTOP,
                                                 ge::VARIABLE, ge::VARIABLEV2 };
 }
 Status AssignRemovePass::Run(NodePtr &node) {
--- a/ge/graph/passes/cast_translate_pass.cc
+++ b/ge/graph/passes/cast_translate_pass.cc
@@ -167,7 +167,7 @@ bool CastTranslatePass::IsOpSupportedOptimize(NodePtr &cast_node, NodePtr &trans
    trans_op_outdesc->SetDataType(cast_out_datatype);
  }
  if (!TranslateCheckAccuracySupported(trans_op_desc)) {
  if (!TranslateCheckAccuracySupported(trans_node)) {
    if (is_src_cast) {
      trans_op_desc->MutableInputDesc(0)->SetDataType(trans_in_datatype);
    } else {
@@ -271,7 +271,8 @@ Status CastTranslatePass::FuseDstNTranslates(NodePtr &node) {
  return SUCCESS;
 }
 bool CastTranslatePass::TranslateCheckAccuracySupported(const OpDescPtr &op_desc) {
 bool CastTranslatePass::TranslateCheckAccuracySupported(NodePtr &node) {
  const OpDescPtr &op_desc = node->GetOpDesc();
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if ((instance_ptr == nullptr) || (!instance_ptr->InitFlag())) {
    GELOGW("GE is not initialized or is finalized.");
@@ -293,7 +294,7 @@ bool CastTranslatePass::TranslateCheckAccuracySupported(const OpDescPtr &op_desc
    auto kernel_info_store = kernel_map.find(kernel_name);
    if (kernel_info_store != kernel_map.end()) {
      if (kernel_info_store->second != nullptr &&
          kernel_info_store->second->CheckAccuracySupported(op_desc, unsupported_reason)) {
          kernel_info_store->second->CheckAccuracySupported(node, unsupported_reason)) {
        return true;
      }
    }
--- a/ge/graph/passes/cast_translate_pass.h
+++ b/ge/graph/passes/cast_translate_pass.h
@@ -35,7 +35,7 @@ class CastTranslatePass : public BaseNodePass {
  bool IsOpSupportedOptimize(NodePtr &cast_node, NodePtr &trans_node, bool &is_src_cast);
  bool CheckOpSupportOptimize(NodePtr &node, bool &is_src_cast);
  Status FuseDstNTranslates(NodePtr &node);
  bool TranslateCheckAccuracySupported(const OpDescPtr &op_desc);
  bool TranslateCheckAccuracySupported(NodePtr &node);
 };
 }  // namespace ge
 #endif  // GE_GRAPH_PASSES_CAST_TRANSLATE_PASS_H_
--- a/ge/graph/passes/compile_nodes_pass.cc
+++ b/ge/graph/passes/compile_nodes_pass.cc
@@ -110,7 +110,7 @@ graphStatus CompileNodesPass::GetSupportedKernel(const NodePtr &node, const std:
    return ge::GE_GRAPH_PARAM_NULLPTR;
  }
  // begin accuracy supported check
  if (!CheckAccuracySupport(kernel_info, instance, op_desc)) {
  if (!CheckAccuracySupport(kernel_info, instance, node)) {
    // if check accuracy support failed , try to go to other engine.
    GELOGD("Check Accuracy Supported return not support, node name is %s. Try to go to other engine.",
           op_desc->GetName().c_str());
@@ -123,7 +123,7 @@ graphStatus CompileNodesPass::GetSupportedKernel(const NodePtr &node, const std:
        continue;
      }
      OpsKernelInfoStorePtr tmp_kernel_info = it->second;
      if (CheckAccuracySupport(tmp_kernel_info, instance, op_desc)) {
      if (CheckAccuracySupport(tmp_kernel_info, instance, node)) {
        kernel_lib_name = tmp_kernel_name;
        GELOGD("Find kernel lib %s support node:%s, type:%s , get kernel lib success.", tmp_kernel_name.c_str(),
               node->GetName().c_str(), op_desc->GetType().c_str());
@@ -138,14 +138,9 @@ graphStatus CompileNodesPass::GetSupportedKernel(const NodePtr &node, const std:
 }
 bool CompileNodesPass::CheckAccuracySupport(const OpsKernelInfoStorePtr &kernel_info,
                                            const std::shared_ptr<GELib> instance, OpDescPtr &op_desc) {
  auto ge_desc = MakeShared<ge::OpDescPtr>(op_desc);
  if (ge_desc == nullptr) {
    GELOGE(GE_GRAPH_MEMORY_ALLOC_FAILED, "Fail to malloc op desc.");
    return false;
  }
                                            const std::shared_ptr<GELib> instance, const NodePtr &node) {
  string reason;
  if (!(kernel_info->CheckAccuracySupported(*ge_desc, reason, true))) {
  if (!(kernel_info->CheckAccuracySupported(node, reason, true))) {
    return false;
  }
  return true;
--- a/ge/graph/passes/compile_nodes_pass.h
+++ b/ge/graph/passes/compile_nodes_pass.h
@@ -39,7 +39,7 @@ class CompileNodesPass : public GraphPass {
 private:
  graphStatus GetSupportedKernel(const NodePtr &node, const std::shared_ptr<GELib> instance, string &kernel_lib_name);
  bool CheckAccuracySupport(const OpsKernelInfoStorePtr &kernel_info, const std::shared_ptr<GELib> instance,
                            OpDescPtr &op_desc);
                            const NodePtr &node);
  graphStatus CompileNodes(const std::shared_ptr<GELib> instance,
                           std::unordered_map<string, vector<NodePtr>> &kernel_to_compile_nodes);
 };
--- a/ge/graph/passes/cond_remove_pass.cc
+++ b/ge/graph/passes/cond_remove_pass.cc
@@ -25,8 +25,9 @@ const uint32_t kElseBranchIndex = 1;
 const uint32_t kTrueIndex = 1;
 const uint32_t kFalseIndex = 0;
 /// Extra 8 bytes store pointer of string
 /// Extra 8 bytes store length of string
 /// Extra 1 byte store '\0'
 const int32_t kStrHeadLen = 9;
 const int32_t kStrHeadLen = sizeof(ge::StringHead) + 1;
 const int32_t kInvalidRetVal = -1;
 }
--- a/ge/graph/passes/constant_folding_pass.cc
+++ b/ge/graph/passes/constant_folding_pass.cc
@@ -50,13 +50,11 @@ Status RunOpKernelWithCheck(NodePtr &node,
  return FoldingPass::RunOpKernel(node, inputs, outputs);
 }
 const std::map<std::string, std::pair<std::uint64_t, uint64_t>>
    &ConstantFoldingPass::GetGeConstantFoldingPerfStatistic() const {
 const map<string, pair<uint64_t, uint64_t>> &ConstantFoldingPass::GetGeConstantFoldingPerfStatistic() const {
  return statistic_of_ge_constant_folding_;
 }
 const std::map<std::string, std::pair<std::uint64_t, uint64_t>>
    &ConstantFoldingPass::GetOpConstantFoldingPerfStatistic() const {
 const map<string, pair<uint64_t, uint64_t>> &ConstantFoldingPass::GetOpConstantFoldingPerfStatistic() const {
  return statistic_of_op_constant_folding_;
 }
--- a/ge/graph/passes/dimension_adjust_pass.cc
+++ b/ge/graph/passes/dimension_adjust_pass.cc
@@ -29,13 +29,13 @@ const int kRemoveInputIndex = 1;
 Status DimensionAdjustPass::Run(ge::NodePtr &node) {
  if (node == nullptr) {
    GELOGE(PARAM_INVALID, "node is nullptr");
    GELOGE(PARAM_INVALID, "node is nullptr.");
    return PARAM_INVALID;
  }
  OpDescPtr op_desc_ptr = node->GetOpDesc();
  if (op_desc_ptr == nullptr) {
    GELOGE(PARAM_INVALID, "GetOpDesc return nullptr");
    GELOGE(PARAM_INVALID, "GetOpDesc return nullptr.");
    return PARAM_INVALID;
  }
--- a/ge/graph/passes/flow_ctrl_pass.cc
+++ b/ge/graph/passes/flow_ctrl_pass.cc
@@ -33,11 +33,11 @@ Status FlowCtrlPass::Run(ComputeGraphPtr compute_graph) {
  GE_CHECK_NOTNULL(compute_graph);
  if (!PassUtils::IsNeedTrainIteFlowCtrl(compute_graph)) {
    GELOGI("No need FlowCtrl for graph %u", compute_graph->GetGraphID());
    GELOGI("No need FlowCtrl for graph %u.", compute_graph->GetGraphID());
    return NOT_CHANGED;
  }
  GELOGI("FlowCtrl pass begin");
  GELOGI("FlowCtrl pass begin.graph is [%s].", compute_graph->GetName().c_str());
  bool graph_change = false;
  // 1. Add FP/BP flow ctrl (big cycle)
  for (auto &node : compute_graph->GetDirectNode()) {
@@ -80,6 +80,16 @@ Status FlowCtrlPass::Run(ComputeGraphPtr compute_graph) {
      graph_change = true;
    }
  }
  // add edge operation below depends on memcpy node in itertor loop set single stream,or may cause block
  for (auto &active_node : active_nodes_in_iter_loop_) {
    auto ret = GraphUtils::AddEdge(active_node->GetOutControlAnchor(),
                                   assign_add_node_in_fpbp_loop_->GetInControlAnchor());
    if (ret != GRAPH_SUCCESS) {
      GELOGW("add control edge between iter_loop_node:%s and fpbp_loop_node:%s fail, may cause block",
             active_node->GetName().c_str(), assign_add_node_in_fpbp_loop_->GetName().c_str());
    }
  }
  GELOGI("FlowCtrl pass end, graph is %s.", graph_change ? "changed" : "not changed");
  return graph_change ? SUCCESS : NOT_CHANGED;
 }
@@ -279,16 +289,16 @@ Status FlowCtrlPass::CreateIterCtrlTrueBranch(ComputeGraphPtr &compute_graph, co
   *         loopIncrement
   */
  // Insert AssignAdd node
  NodePtr assign_add_node =
  assign_add_node_in_fpbp_loop_ =
      InsertAssignOp(compute_graph, ASSIGNADD, NODE_NAME_FLOWCTRL_LOOP_ASSIGNADD, loop_cond_node, loop_inc_node);
  if (assign_add_node == nullptr || switch_node == nullptr) {
  if (assign_add_node_in_fpbp_loop_ == nullptr || switch_node == nullptr) {
    GELOGE(PARAM_INVALID, "assign add node or switch node is null");
    return FAILED;
  }
  string active_name = switch_node->GetName() + "_StreamActive";
  // add attr for stream assign model to break branch.
  GE_CHK_STATUS_RET(SetStreamLabel(assign_add_node, active_name), "set stream label failed");
  GE_CHK_STATUS_RET(SetStreamLabel(assign_add_node_in_fpbp_loop_, active_name), "set stream label failed");
  // used for stream assign to find true branch
  GE_CHK_STATUS_RET(SetActiveLabelList(switch_node, { active_name }), "set active label list failed");
@@ -304,13 +314,15 @@ Status FlowCtrlPass::CreateIterCtrlTrueBranch(ComputeGraphPtr &compute_graph, co
                    DOMI_LOGE("set ATTR_NAME_IS_LOOP_ACTIVE failed"); return FAILED);
  // add ctrl edges
  graphStatus add_ret = GraphUtils::AddEdge(switch_node->GetOutControlAnchor(), assign_add_node->GetInControlAnchor());
  graphStatus add_ret = GraphUtils::AddEdge(switch_node->GetOutControlAnchor(),
                                            assign_add_node_in_fpbp_loop_->GetInControlAnchor());
  if (add_ret != GRAPH_SUCCESS) {
    GELOGE(FAILED, "Add switch_node to assign_add_node ctrl edge failed, add_ret=%u.", add_ret);
    return FAILED;
  }
  add_ret = GraphUtils::AddEdge(assign_add_node->GetOutControlAnchor(), active_node->GetInControlAnchor());
  add_ret = GraphUtils::AddEdge(assign_add_node_in_fpbp_loop_->GetOutControlAnchor(),
                                active_node->GetInControlAnchor());
  if (add_ret != GRAPH_SUCCESS) {
    GELOGE(FAILED, "Add assign_add_node to active_node ctrl edge failed, add_ret=%u.", add_ret);
    return FAILED;
@@ -335,11 +347,11 @@ Status FlowCtrlPass::CreateIterCtrlFalseBranch(ComputeGraphPtr &compute_graph, c
  NodePtr assign_node =
      InsertAssignOp(compute_graph, ASSIGN, NODE_NAME_FLOWCTRL_LOOP_ASSIGN, loop_cond_node, loop_reset_node);
  if (assign_node == nullptr || switch_node == nullptr) {
    GELOGE(PARAM_INVALID, "assign_node or switch node is null");
    GELOGE(PARAM_INVALID, "assign_node or switch node is null.");
    return FAILED;
  }
  GE_CHK_STATUS_RET(SetStreamLabel(assign_node, switch_node->GetName()), "set stream label failed");
  GE_CHK_STATUS_RET(SetStreamLabel(assign_node, switch_node->GetName()), "set stream label failed.");
  graphStatus add_ret = GraphUtils::AddEdge(switch_node->GetOutControlAnchor(), assign_node->GetInControlAnchor());
  if (add_ret != GRAPH_SUCCESS) {
@@ -358,7 +370,7 @@ Status FlowCtrlPass::CreateIterCtrlFalseBranch(ComputeGraphPtr &compute_graph, c
    }
    GE_CHK_STATUS_RET(SetStreamLabel(active_node, switch_node->GetName()), "set stream label failed");
    GE_CHK_STATUS_RET(SetSwitchBranchNodeLabel(active_node, switch_node->GetName()),
                      "set switch branch node label failed");
                      "set switch branch node label failed.");
    string model_exit_name = switch_node->GetName() + "_ModelExit";
    GE_CHK_STATUS_RET(SetActiveLabelList(active_node, { model_exit_name }), "set active label list failed");
@@ -389,7 +401,7 @@ Status FlowCtrlPass::CreateIterCtrlFalseBranch(ComputeGraphPtr &compute_graph, c
 }
 Status FlowCtrlPass::AddFpBpIteratorCtrl(ComputeGraphPtr &compute_graph, NodePtr &pre_node) {
  GE_IF_BOOL_EXEC(pre_node == nullptr, DOMI_LOGE("pre_node is nullptr"); return FAILED);
  GE_IF_BOOL_EXEC(pre_node == nullptr, DOMI_LOGE("pre_node is nullptr."); return FAILED);
  string pre_node_name = pre_node->GetName();
  GELOGI("Add FpBp Iterator ctrl, pre node:%s.", pre_node_name.c_str());
  // 1. Get or add variables
@@ -465,7 +477,7 @@ Status FlowCtrlPass::AddSpecialNodeIteratorCtrl(ComputeGraphPtr &compute_graph,
   *          itersPerLoop  loopCond
   */
  GE_IF_BOOL_EXEC(loop_after_node == nullptr || compute_graph == nullptr,
          DOMI_LOGE("loop after node or compute graph is null"); return FAILED);
          DOMI_LOGE("loop after node or compute graph is null."); return FAILED);
  InDataAnchorPtr in_anchor = loop_after_node->GetInDataAnchor(0);
  if (in_anchor == nullptr || in_anchor->GetPeerOutAnchor() == nullptr) {
    GELOGE(FAILED, "Find %s in data anchor failed.", loop_after_node->GetName().c_str());
@@ -486,7 +498,7 @@ Status FlowCtrlPass::AddSpecialNodeIteratorCtrl(ComputeGraphPtr &compute_graph,
  }
  // 2. Add StreamSwitch and edges to switch_node.
  GE_IF_BOOL_EXEC(loop_pre_node == nullptr, DOMI_LOGE("loop pre node is null"); return FAILED);
  GE_IF_BOOL_EXEC(loop_pre_node == nullptr, DOMI_LOGE("loop pre node is null."); return FAILED);
  string switch_name = loop_pre_node->GetName() + "_" + NODE_NAME_STREAM_SWITCH;
  NodePtr switch_node = InsertStreamSwitchOp(compute_graph, switch_name, loop_cond_node, iter_per_loop_node);
  if (switch_node == nullptr) {
@@ -494,7 +506,7 @@ Status FlowCtrlPass::AddSpecialNodeIteratorCtrl(ComputeGraphPtr &compute_graph,
    return FAILED;
  }
  GE_CHK_STATUS_RET(SetStreamLabel(switch_node, switch_name), "set stream label failed");
  GE_CHK_STATUS_RET(SetStreamLabel(switch_node, switch_name), "set stream label failed.");
  graphStatus add_ret = GraphUtils::AddEdge(loop_pre_node->GetOutControlAnchor(), switch_node->GetInControlAnchor());
  if (add_ret != GRAPH_SUCCESS) {
@@ -517,7 +529,7 @@ Status FlowCtrlPass::AddSpecialNodeIteratorCtrl(ComputeGraphPtr &compute_graph,
    return FAILED;
  }
  GE_CHK_STATUS_RET(SetStreamLabel(active_node, active_name), "set stream label failed");
  GE_CHK_STATUS_RET(SetStreamLabel(active_node, active_name), "set stream label failed.");
  GE_IF_BOOL_EXEC(!AttrUtils::SetBool(active_node->GetOpDesc(), ATTR_NAME_IS_LOOP_ACTIVE, true),
                    DOMI_LOGE("set ATTR_NAME_IS_LOOP_ACTIVE failed"); return FAILED);
@@ -530,9 +542,10 @@ Status FlowCtrlPass::AddSpecialNodeIteratorCtrl(ComputeGraphPtr &compute_graph,
  }
  // used for stream assign to find true branch
  GE_CHK_STATUS_RET(SetActiveLabelList(switch_node, { active_name }), "set active label list failed");
  GE_CHK_STATUS_RET(SetActiveLabelList(switch_node, { active_name }), "set active label list failed.");
  // used for stream assign to find active stream
  GE_CHK_STATUS_RET(SetActiveLabelList(active_node, { loop_pre_node->GetName() }), "set active label list failed");
  active_nodes_in_iter_loop_.push_back(active_node);
  return SUCCESS;
 }
 }  // namespace ge
--- a/ge/graph/passes/flow_ctrl_pass.h
+++ b/ge/graph/passes/flow_ctrl_pass.h
@@ -142,6 +142,9 @@ class FlowCtrlPass : public GraphPass {
  ///         false: only one dataSet exist
  ///
  bool CheckMultiDataSet(ComputeGraphPtr &compute_graph);
  NodePtr assign_add_node_in_fpbp_loop_ = nullptr;
  std::vector<NodePtr> active_nodes_in_iter_loop_;
 };
 }  // namespace ge
--- a/ge/graph/passes/hccl_continuous_memcpy_pass.cc
+++ b/ge/graph/passes/hccl_continuous_memcpy_pass.cc
@@ -140,7 +140,8 @@ bool HcclContinuousMemcpyPass::IsDataNode(const std::string& node_type) {
 /// @param [in] ge::OutDataAnchorPtr in_node
 /// @return ge::NodePtr
 ///
 NodePtr HcclContinuousMemcpyPass::CreateIdentityNode(const ComputeGraphPtr &graph, const OutDataAnchorPtr &out_data_anchor) {
 NodePtr HcclContinuousMemcpyPass::CreateIdentityNode(const ComputeGraphPtr &graph,
                                                     const OutDataAnchorPtr &out_data_anchor) {
  GE_CHECK_NOTNULL_EXEC(graph, return nullptr);
  NodePtr pre_node = out_data_anchor->GetOwnerNode();
  OpDescPtr pre_op_desc = pre_node->GetOpDesc();
@@ -205,8 +206,9 @@ std::string HcclContinuousMemcpyPass::CheckDuplicateName(const std::string &node
 /// @param [in] InDataAnchorPtr hccl_in_anchor
 /// @return status
 ///
 Status HcclContinuousMemcpyPass::ModifyEdgeConnection(const ComputeGraphPtr &graph, const OutDataAnchorPtr &src_out_anchor,
                                            const InDataAnchorPtr &hccl_in_anchor) {
 Status HcclContinuousMemcpyPass::ModifyEdgeConnection(const ComputeGraphPtr &graph,
                                                      const OutDataAnchorPtr &src_out_anchor,
                                                      const InDataAnchorPtr &hccl_in_anchor) {
  GE_CHECK_NOTNULL(src_out_anchor->GetOwnerNode());
  GE_CHECK_NOTNULL(hccl_in_anchor->GetOwnerNode());
@@ -235,8 +237,9 @@ Status HcclContinuousMemcpyPass::ModifyEdgeConnection(const ComputeGraphPtr &gra
 /// @param [in] InDataAnchorPtr hccl_in_anchor
 /// @return status
 ///
 Status HcclContinuousMemcpyPass::InsertIdentityBeforeHccl(const ComputeGraphPtr &graph, const OutDataAnchorPtr &src_out_anchor,
                                                const InDataAnchorPtr &hccl_in_anchor) {
 Status HcclContinuousMemcpyPass::InsertIdentityBeforeHccl(const ComputeGraphPtr &graph,
                                                          const OutDataAnchorPtr &src_out_anchor,
                                                          const InDataAnchorPtr &hccl_in_anchor) {
  GELOGI("Between op %s and op %s need insert memcpy async op.", src_out_anchor->GetOwnerNode()->GetName().c_str(),
         hccl_in_anchor->GetOwnerNode()->GetName().c_str());
  NodePtr memcpy_node = CreateIdentityNode(graph, src_out_anchor);
@@ -274,8 +277,8 @@ Status HcclContinuousMemcpyPass::InsertIdentityBeforeHccl(const ComputeGraphPtr
 /// @return status
 ///
 Status HcclContinuousMemcpyPass::InsertAssignAfterBroadcastIfNeed(const ComputeGraphPtr &graph,
                                                        const OutDataAnchorPtr &var_out_anchor,
                                                        const InDataAnchorPtr &hccl_in_anchor) {
                                                                  const OutDataAnchorPtr &var_out_anchor,
                                                                  const InDataAnchorPtr &hccl_in_anchor) {
  if (hccl_in_anchor->GetOwnerNode()->GetType() != HCOMBROADCAST) {
    GELOGD("%s not broadcast, no need to insert assign node", hccl_in_anchor->GetOwnerNode()->GetName().c_str());
    return SUCCESS;
@@ -354,8 +357,9 @@ Status HcclContinuousMemcpyPass::InsertAssignAfterBroadcastIfNeed(const ComputeG
 /// @param [in] ge::OutDataAnchorPtr variable node out anchor
 /// @return ge::NodePtr
 ///
 NodePtr HcclContinuousMemcpyPass::CreateAssignNode(const ComputeGraphPtr &graph, const OutDataAnchorPtr &out_data_anchor) {
  GE_CHECK_NOTNULL_EXEC(graph , return nullptr);
 NodePtr HcclContinuousMemcpyPass::CreateAssignNode(const ComputeGraphPtr &graph,
                                                   const OutDataAnchorPtr &out_data_anchor) {
  GE_CHECK_NOTNULL_EXEC(graph, return nullptr);
  NodePtr pre_node = out_data_anchor->GetOwnerNode();
  OpDescPtr pre_op_desc = pre_node->GetOpDesc();
  if (pre_op_desc == nullptr) {
--- a/ge/graph/passes/inplace_support_check_pass.cc
+++ b/ge/graph/passes/inplace_support_check_pass.cc
@@ -23,9 +23,9 @@ namespace ge {
 namespace {
 constexpr uint32_t kInplaceSupportOutputIndex = 0;
 constexpr uint32_t kInplaceSupportOutputNum = 1;
 static const std::set<std::string> kSrcNodeTypes = { ge::DATA, ge::ANN_DATA, ge::AIPPDATA,
                                                     ge::CONSTANT, ge::CONSTANTOP,
                                                     ge::VARIABLE, ge::VARIABLEV2 };
 const std::set<std::string> kSrcNodeTypes = { ge::DATA, ge::ANN_DATA, ge::AIPPDATA,
                                              ge::CONSTANT, ge::CONSTANTOP,
                                              ge::VARIABLE, ge::VARIABLEV2 };
 }
 Status InplaceSupportCheckPass::Run(NodePtr &node) {
  GELOGD("InplaceSupportCheckPass running");
--- a/ge/graph/passes/net_output_pass.cc
+++ b/ge/graph/passes/net_output_pass.cc
@@ -458,7 +458,7 @@ Status NetOutputPass::Run(ge::ComputeGraphPtr graph) {
    GELOGE(GE_GRAPH_PARAM_NULLPTR, "Compute graph is null.");
    return GE_GRAPH_PARAM_NULLPTR;
  }
  GELOGI("NetOutputPass Run.");
  GELOGI("NetOutputPass Run.graph is [%s]", graph->GetName().c_str());
  NodePtr output_node = graph->FindFirstNodeMatchType(NETOUTPUT);
  // save user targets node
  SaveAndRemoveTargets(graph);
--- a/ge/graph/passes/no_use_reshape_remove_pass.cc
+++ b/ge/graph/passes/no_use_reshape_remove_pass.cc
@@ -82,14 +82,41 @@ Status NoUseReshapeRemovePass::Run(ge::NodePtr &node) {
    }
  }
  if (to_be_deleted) {
    GELOGI("NoUseReshapeRemovePass remove useless node:%s", node->GetName().c_str());
    auto ret = PassUtils::UnlinkNodeWithControlCopy(node, kReshapeShapeIndex);
    if (ret != SUCCESS) {
      GELOGE(ret, "DimensionAdjustPass unlink node with control copy fail.");
      return ret;
    }
    auto ret = TryRemoveConstShapeInput(node);
    GE_CHK_STATUS_RET_NOLOG(ret);
    GELOGI("NoUseReshapeRemovePass remove useless reshape node:%s", node->GetName().c_str());
    return IsolateAndDeleteNode(node, {kReshapeDataIndex});
  }
  return SUCCESS;
 }
 Status NoUseReshapeRemovePass::TryRemoveConstShapeInput(ge::NodePtr &reshape_node) {
  auto shape_input_anchor = reshape_node->GetInDataAnchor(kReshapeShapeIndex);
  if (shape_input_anchor == nullptr) {
    return SUCCESS;
  }
  GE_CHECK_NOTNULL(shape_input_anchor->GetPeerOutAnchor());
  auto shape_input = shape_input_anchor->GetPeerOutAnchor()->GetOwnerNode();
  GE_CHECK_NOTNULL(shape_input);
  if (shape_input->GetType() != CONSTANT && shape_input->GetType() != CONSTANTOP) {
    return SUCCESS;
  }
  //   op(x)   const(shape)
  //     \     /
  //     reshape
  // const input can unlink but should copy control_dependency
  auto ret = PassUtils::UnlinkNodeWithControlCopy(reshape_node, kReshapeShapeIndex);
  if (ret != SUCCESS) {
    GELOGE(ret, "Unlink node %s with control copy failed.", shape_input->GetName().c_str());
    return ret;
  }
  // remove const without any data_output
  if (shape_input->GetOutDataNodesSize() == 0) {
    auto ret = IsolateAndDeleteNode(shape_input, {});
    GE_CHK_GRAPH_STATUS_RET(ret, "Fail to remove node %s", shape_input->GetName().c_str());
    GELOGI("Remove useless shape input const %s.", shape_input->GetName().c_str());
  }
  return SUCCESS;
 }
 }  // namespace ge
--- a/ge/graph/passes/no_use_reshape_remove_pass.h
+++ b/ge/graph/passes/no_use_reshape_remove_pass.h
@@ -32,6 +32,9 @@ class NoUseReshapeRemovePass : public BaseNodePass {
  /// @author
  ///
  Status Run(ge::NodePtr &node) override;
 private:
  Status TryRemoveConstShapeInput(NodePtr &reshape_node);
 };
 }  // namespace ge
--- a/ge/graph/passes/prune_pass.cc
+++ b/ge/graph/passes/prune_pass.cc
@@ -27,12 +27,11 @@
 namespace ge {
 Status PrunePass::Run(ge::ComputeGraphPtr graph) {
  GELOGD("PrunePass Start");
  GELOGD("PrunePass Start, graph is [%s]", graph->GetName().c_str());
  if (graph == nullptr) {
    GELOGE(GE_GRAPH_ISNULL, "input compute graph is NULL.");
    return GE_GRAPH_ISNULL;
  }
  std::vector<NodePtr> out_nodes;
  std::unordered_set<NodePtr> nodes;
  for (NodePtr &node_ptr : graph->GetDirectNode()) {
@@ -42,7 +41,6 @@ Status PrunePass::Run(ge::ComputeGraphPtr graph) {
      out_nodes.push_back(node_ptr);
    }
  }
  if (out_nodes.empty()) {
    GELOGW("graph [%s] does not contain NETOUTPUT type node,no return value. Do nothing!", graph->GetName().c_str());
    return ge::SUCCESS;
--- a/ge/graph/passes/replace_with_empty_const_pass.cc
+++ b/ge/graph/passes/replace_with_empty_const_pass.cc
@@ -33,7 +33,7 @@ Status ReplaceWithEmptyConstPass::Run(NodePtr &node) {
    GELOGE(PARAM_INVALID, "Param [opDesc] must not be null.");
    return PARAM_INVALID;
  }
  if (node->GetType() == CONSTANT || node->GetType() == CONSTANTOP) {
  if (node->GetType() == CONSTANT || node->GetType() == CONSTANTOP || node->GetType() == DATA) {
    GELOGI("Node %s is const. Ignore current pass.", node->GetName().c_str());
    return SUCCESS;
  }
--- a/ge/graph/passes/reshape_remove_pass.cc
+++ b/ge/graph/passes/reshape_remove_pass.cc
@@ -43,7 +43,7 @@ Status ReshapeRemovePass::Run(NodePtr &node) {
  GE_CHECK_NOTNULL(node);
  GE_CHECK_NOTNULL(node->GetOpDesc());
  int key = kToBeDeleteOp.find(node->GetType()) == kToBeDeleteOp.end() ? kOpNoDelete : kToBeDeleteOp[node->GetType()];
  switch(key) {
  switch (key) {
    case kReshapeType: {
      bool is_shape_unknown = false;
      if (NodeUtils::GetNodeUnknownShapeStatus(*node, is_shape_unknown) == GRAPH_SUCCESS) {
--- a/ge/graph/passes/resource_pair_add_control_pass.cc
+++ b/ge/graph/passes/resource_pair_add_control_pass.cc
@@ -63,16 +63,17 @@ Status ResourcePairAddControlPass::Run(ComputeGraphPtr graph) {
        NodePtr from_node = prefix_2_node.second;
        GE_CHECK_NOTNULL(from_node);
        auto to_item_prefix_2_node = prefix_2_node_per_type.find(resource_type_pair.second);
        // stackpush and stackpop may exist in two subgraphs, no necessary to report error
        if (to_item_prefix_2_node == prefix_2_node_per_type.end()) {
          GELOGE(PARAM_INVALID, "find peer type node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
          GELOGW("find peer type node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
                 resource_type_pair.first.c_str(), resource_type_pair.second.c_str());
          return PARAM_INVALID;
          continue;
        }
        auto to_prefix_2_node = to_item_prefix_2_node->second.find(prefix);
        if (to_prefix_2_node == to_item_prefix_2_node->second.end()) {
          GELOGE(PARAM_INVALID, "find peer prefix node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
          GELOGW("find peer prefix node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
                 resource_type_pair.first.c_str(), resource_type_pair.second.c_str());
          return PARAM_INVALID;
          continue;
        }
        NodePtr to_node = to_prefix_2_node->second;
        GE_CHECK_NOTNULL(to_node);
--- a/ge/graph/passes/resource_pair_remove_control_pass.cc
+++ b/ge/graph/passes/resource_pair_remove_control_pass.cc
@@ -63,16 +63,17 @@ Status ResourcePairRemoveControlPass::Run(ComputeGraphPtr graph) {
        NodePtr from_node = prefix_2_node.second;
        GE_CHECK_NOTNULL(from_node);
        auto to_item_prefix_2_node = prefix_2_node_per_type.find(resource_type_pair.second);
        // stackpush and stackpop may exist in two subgraphs, no necessary to report error
        if (to_item_prefix_2_node == prefix_2_node_per_type.end()) {
          GELOGE(INTERNAL_ERROR, "find peer type node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
          GELOGW("find peer type node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
                 resource_type_pair.first.c_str(), resource_type_pair.second.c_str());
          return domi::PARAM_INVALID;
          continue;
        }
        auto to_prefix_2_node = to_item_prefix_2_node->second.find(prefix);
        if (to_prefix_2_node == to_item_prefix_2_node->second.end()) {
          GELOGE(INTERNAL_ERROR, "find peer prefix node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
          GELOGW("find peer prefix node fail, suffix:%s, from_type:%s, to_type:%s", prefix.c_str(),
                 resource_type_pair.first.c_str(), resource_type_pair.second.c_str());
          return domi::PARAM_INVALID;
          continue;
        }
        NodePtr to_node = to_prefix_2_node->second;
        GE_CHECK_NOTNULL(to_node);
--- a/ge/graph/passes/same_transdata_breadth_fusion_pass.cc
+++ b/ge/graph/passes/same_transdata_breadth_fusion_pass.cc
@@ -67,7 +67,7 @@ OpDescPtr SameTransdataBreadthFusionPass::GetCastOp(const GeTensorDesc &in_desc,
  auto fusion_cast_op_count = atomic_fusion_cast_op_count.fetch_add(1);
  std::stringstream cast_op_name;
  cast_op_name << "fusion_cast_" << fusion_cast_op_count;
  auto node_op = ge::OperatorFactory::CreateOperator(cast_op_name.str(), CAST);
  auto node_op = ge::OperatorFactory::CreateOperator(cast_op_name.str().c_str(), CAST);
  auto cast_op = ge::OpDescUtils::GetOpDescFromOperator(node_op);
  node_op.BreakConnect();
  if (cast_op == nullptr) {
--- a/ge/graph/passes/subexpression_migration_pass.cc
+++ b/ge/graph/passes/subexpression_migration_pass.cc
@@ -165,14 +165,6 @@ Status SubexpressionMigrationPass::ClassifyDataNodes(const ComputeGraphPtr &grap
    }
  }
  for (const auto &data_nodes : graph_nodes) {
    if (data_nodes.second.size() != graph_nodes.begin()->second.size()) {
      GELOGE(FAILED, "Subgraph %s has invalid Data nodes[%zu != %zu]",
             data_nodes.first->GetName().c_str(), data_nodes.second.size(), graph_nodes.begin()->second.size());
      return FAILED;
    }
  }
  return SUCCESS;
 }
--- a/ge/graph/passes/subgraph_const_migration_pass.cc
+++ b/ge/graph/passes/subgraph_const_migration_pass.cc
@@ -385,7 +385,7 @@ Status SubgraphConstMigrationPass::DetachParallelNode(const ComputeGraphPtr &gra
  // Break Move and follow, Link Data and follow.
  const auto &out_anchor = const_node->GetOutDataAnchor(kZeroIndex);
  const auto in_anchors =out_anchor->GetPeerInDataAnchors();
  const auto in_anchors = out_anchor->GetPeerInDataAnchors();
  for (const auto in_anchor : in_anchors) {
    GE_CHK_GRAPH_STATUS_RET(GraphUtils::RemoveEdge(out_anchor, in_anchor), "Remove edge failed");
    GELOGI("Remove Edge: %s %s", const_node->GetName().c_str(), in_anchor->GetOwnerNode()->GetName().c_str());
--- a/ge/graph/passes/transpose_transdata_pass.cc
+++ b/ge/graph/passes/transpose_transdata_pass.cc
@@ -86,7 +86,7 @@ Status TransposeTransDataPass::Run(NodePtr &node) {
    if (CheckOneInAndOneOutDataAnchor(out_node)) {
      return FAILED;
    }
    if (!FusionIfNeed(op_desc, out_op_desc)) {
    if (!FusionIfNeed(op_desc, out_node)) {
      continue;
    }
    CopyInputEdges(node, out_node);
@@ -152,7 +152,8 @@ Status TransposeTransDataPass::RemoveTranspose(NodePtr &node) {
  return SUCCESS;
 }
 bool TransposeTransDataPass::FusionIfNeed(OpDescPtr &op_desc, OpDescPtr &transdata_op_desc) {
 bool TransposeTransDataPass::FusionIfNeed(OpDescPtr &op_desc, NodePtr &node) {
  auto transdata_op_desc = node->GetOpDesc();
  GE_CHECK_NOTNULL(op_desc);
  GE_CHECK_NOTNULL(transdata_op_desc);
  auto out_input_desc = transdata_op_desc->MutableInputDesc(0);
@@ -187,7 +188,7 @@ bool TransposeTransDataPass::FusionIfNeed(OpDescPtr &op_desc, OpDescPtr &transda
  out_input_desc->SetFormat(src_format);
  out_input_desc->SetShape(src_shape);
  if (!TransDataCheckAccuracySupported(transdata_op_desc)) {
  if (!TransDataCheckAccuracySupported(node)) {
    out_input_desc->SetFormat(out_input_format);
    out_input_desc->SetShape(out_input_shape);
    return false;
@@ -224,7 +225,8 @@ void TransposeTransDataPass::CopyInputEdges(NodePtr &origin_node, NodePtr &new_n
    GraphUtils::CopyInCtrlEdges(origin_node, new_node) != GRAPH_SUCCESS, GELOGW("Copy in ctrl edges failed"); return);
 }
 bool TransposeTransDataPass::TransDataCheckAccuracySupported(const OpDescPtr &op_desc) {
 bool TransposeTransDataPass::TransDataCheckAccuracySupported(NodePtr &node) {
  const OpDescPtr &op_desc = node->GetOpDesc();
  std::shared_ptr<GELib> instance_ptr = ge::GELib::GetInstance();
  if ((instance_ptr == nullptr) || (!instance_ptr->InitFlag())) {
    GELOGW("GELib not initialized");
@@ -244,7 +246,7 @@ bool TransposeTransDataPass::TransDataCheckAccuracySupported(const OpDescPtr &op
    auto &kernel_name = it.opKernelLib;
    auto kernel_info_store = kernel_map.find(kernel_name);
    if (kernel_info_store != kernel_map.end()) {
      if (kernel_info_store->second->CheckAccuracySupported(op_desc, unsupported_reason, true)) {
      if (kernel_info_store->second->CheckAccuracySupported(node, unsupported_reason, true)) {
        return true;
      }
    }
--- a/ge/graph/passes/transpose_transdata_pass.h
+++ b/ge/graph/passes/transpose_transdata_pass.h
@@ -26,9 +26,9 @@ class TransposeTransDataPass : public BaseNodePass {
 private:
  Status CheckOneInAndOneOutDataAnchor(NodePtr &node) const;
  Status RemoveTranspose(NodePtr &node);
  bool FusionIfNeed(OpDescPtr &op_desc, OpDescPtr &transdata_op_desc);
  bool FusionIfNeed(OpDescPtr &op_desc, NodePtr &node);
  void CopyInputEdges(NodePtr &origin_node, NodePtr &new_node);
  bool TransDataCheckAccuracySupported(const OpDescPtr &op_desc);
  bool TransDataCheckAccuracySupported(NodePtr &node);
 };
 }  // namespace ge
 #endif  // GE_GRAPH_PASSES_TRANSPOSE_TRANSDATA_PASS_H_
--- a/ge/graph/preprocess/graph_preprocess.cc
+++ b/ge/graph/preprocess/graph_preprocess.cc
@@ -991,7 +991,6 @@ Status ParseDynamicInputShapeRange(const std::string &shape_range,
 Status GetDynamicInputShapeRange(const std::vector<GeTensor> &user_input, const std::map<string, string> &graph_option,
                                 vector<vector<std::pair<int64_t, int64_t>>> &range_vec) {
  // check both mode and shape_range option are all enabled
  auto mode_iter = graph_option.find(OPTION_EXEC_DYNAMIC_EXECUTE_MODE);
  bool enable_dynamic_execute_mode = (mode_iter != graph_option.end()) && (mode_iter->second == "dynamic_execute");
  if (!enable_dynamic_execute_mode) {
@@ -1272,9 +1271,10 @@ Status GraphPrepare::AdjustDataOpOutput(const NodePtr &node) {
  return SUCCESS;
 }
 Status GraphPrepare::UpdateInput(const std::vector<GeTensor> &user_input, const std::map<string,string> &graph_option) {
 Status GraphPrepare::UpdateInput(const std::vector<GeTensor> &user_input,
                                 const std::map<string, string> &graph_option) {
  // Get shape range of input in dynamic_execute mode
  vector<vector<std::pair<int64_t,int64_t>>> dynamic_shape_range_vec;
  vector<vector<std::pair<int64_t, int64_t>>> dynamic_shape_range_vec;
  auto ret = GetDynamicInputShapeRange(user_input, graph_option, dynamic_shape_range_vec);
  GE_CHK_STATUS_RET(ret, "Graph option is not right on Dynamic execute mode.");
  compute_graph_->SaveDataFormat(ge::TypeUtils::DomiFormatToFormat(GetLocalOmgContext().format));
@@ -2012,7 +2012,8 @@ Status GraphPrepare::ProcessNetOutput() {
  return SUCCESS;
 }
 Status GraphPrepare::CheckAndUpdateInput(const std::vector<GeTensor> &user_input,const std::map<string,string> &graph_option) {
 Status GraphPrepare::CheckAndUpdateInput(const std::vector<GeTensor> &user_input,
                                         const std::map<string, string> &graph_option) {
  compute_graph_->SetInputSize(user_input.size());
  if (user_input.empty()) {
    return SUCCESS;
--- a/ge/graph/preprocess/graph_preprocess.h
+++ b/ge/graph/preprocess/graph_preprocess.h
@@ -23,7 +23,7 @@
 #include <vector>
 #include "common/debug/log.h"
 #include "common/debug/memory_dumper.h"
 #include "common/model_parser/base.h"
 #include "common/model_parser/model_parser.h"
 #include "common/properties_manager.h"
 #include "common/string_util.h"
 #include "common/types.h"
@@ -63,8 +63,8 @@ class GraphPrepare {
  Status CheckRefOp();
  Status SetRtContext(rtContext_t rt_context, rtCtxMode_t mode);
  Status AdjustDataOpOutput(const NodePtr &node);
  Status UpdateInput(const std::vector<GeTensor> &user_input, const std::map<string,string> &graph_option);
  Status CheckAndUpdateInput(const std::vector<GeTensor> &user_input, const std::map<string,string> &graph_option);
  Status UpdateInput(const std::vector<GeTensor> &user_input, const std::map<string, string> &graph_option);
  Status CheckAndUpdateInput(const std::vector<GeTensor> &user_input, const std::map<string, string> &graph_option);
  Status CheckConstOp();
  Status VerifyConstOp(const NodePtr &node);
  Status CheckUserInput(const std::vector<GeTensor> &user_input);
--- a/ge/graph/preprocess/multi_batch_copy_graph.cc
+++ b/ge/graph/preprocess/multi_batch_copy_graph.cc
@@ -600,7 +600,7 @@ Status MultiBatchGraphCopyer::LabelInBatchBranchStatus() {
      for (auto &in_node : node->GetInDataNodes()) {
        if (origin_nodes_status_.find(in_node.get()) != origin_nodes_status_.end()) {
          if (origin_nodes_status_.find(node.get()) == origin_nodes_status_.end()) {
            origin_nodes_status_[node.get()] == kNodeInBatchBranch;
            origin_nodes_status_[node.get()] = kNodeInBatchBranch;
            ResetEnterStatus(frame_enters, node);
            changed = true;
          }
--- a/ge/graph/preprocess/multi_batch_options.h
+++ b/ge/graph/preprocess/multi_batch_options.h
@@ -105,7 +105,7 @@ GE_FUNC_VISIBILITY bool CheckDynamicBatchShape(const vector<int64_t> &shape, con
 /// @return 0: true/false
 ///
 GE_FUNC_VISIBILITY bool CheckDynamicImageSizeShape(const vector<int64_t> &shape, const string &data_name,
                                const std::string &input_format);
                                                   const std::string &input_format);
 }  // namespace multibatch
 }  // namespace ge
--- a/ge/host_kernels/dynamic_stitch_kernel.cc
+++ b/ge/host_kernels/dynamic_stitch_kernel.cc
@@ -111,8 +111,9 @@ void DynamicStitchKernel::ComputeMergedShape(const vector<ConstGeTensorPtr> &inp
  int32_t merged_first_dim = 0;
  int64_t indices_shape_size = 0;
  for (int i = 0; i < n_; i++) {
    indices_shape_size = input[i]->GetTensorDesc().GetShape().GetShapeSize();
    indices_shape_size = indices_shape_size == 0 ? 1 : indices_shape_size;
    // shape is [] means scalar
    indices_shape_size =
      input[i]->GetTensorDesc().GetShape().GetDims().empty() ? 1 : input[i]->GetTensorDesc().GetShape().GetShapeSize();
    const int32_t *input_indices = reinterpret_cast<const int32_t *>(input[i]->GetData().data());
    for (int64_t j = 0; j < indices_shape_size; j++) {
      merged_first_dim = std::max(merged_first_dim, input_indices[j]);
--- a/ge/host_kernels/slice_kernel.cc
+++ b/ge/host_kernels/slice_kernel.cc
@@ -16,6 +16,8 @@
 #include "host_kernels/slice_kernel.h"
 #include <set>
 #include "common/ge_inner_error_codes.h"
 #include "common/op/ge_op_utils.h"
 #include "common/types.h"
@@ -31,6 +33,30 @@ const size_t kSliceInputSize = 3;
 const size_t kSliceInputIndexX = 0;
 const size_t kSliceInputIndexBegin = 1;
 const size_t kSliceInputIndexSize = 2;
 const std::set<ge::DataType> kSupportedDataTypeToLength = {
    DT_BOOL,
    DT_INT64,
    DT_UINT64,
    DT_FLOAT,
    DT_INT32,
    DT_UINT32,
    DT_INT8,
    DT_UINT8,
    DT_INT16,
    DT_UINT16,
    DT_FLOAT16,
    DT_DOUBLE,
    DT_DUAL,
    DT_DUAL_SUB_INT8,
    DT_DUAL_SUB_UINT8,
    DT_COMPLEX64,
    DT_COMPLEX128,
    DT_QINT8,
    DT_QINT16,
    DT_QINT32,
    DT_QUINT8,
    DT_QUINT16,
 };
 }  // namespace
 Status SliceKernel::Compute(const OpDescPtr attr, const std::vector<ConstGeTensorPtr> &input,
@@ -56,6 +82,16 @@ Status SliceKernel::Compute(const OpDescPtr attr, const std::vector<ConstGeTenso
  // data type in input_x
  auto data_type = x_->GetTensorDesc().GetDataType();
  // check supported
  if (kSupportedDataTypeToLength.count(data_type) == 0) {
    GELOGW("input_x data_type is [%s], does not supported!", TypeUtils::DataTypeToSerialString(data_type).c_str());
    return NOT_CHANGED;
  }
  uint32_t type_size = 0;
  bool is_success = TypeUtils::GetDataTypeLength(data_type, type_size);
  if (!is_success) {
    return NOT_CHANGED;
  }
  // check data type of begin and size
  if (begin->GetTensorDesc().GetDataType() != DT_INT32 || size->GetTensorDesc().GetDataType() != DT_INT32) {
    GELOGW("Data type of begin and size for slice are not DT_INT32.");
@@ -69,7 +105,7 @@ Status SliceKernel::Compute(const OpDescPtr attr, const std::vector<ConstGeTenso
  GE_CHECK_NOTNULL(begin_data);
  GE_CHECK_NOTNULL(size_data);
  size_t data_size = x_->GetData().size() / sizeof(int32_t);
  size_t data_size = x_->GetData().size() / type_size;
  size_t begin_size = begin->GetData().size() / sizeof(int32_t);
  size_t size_size = size->GetData().size() / sizeof(int32_t);
  const ge::GeShape &x_shape = x_->GetTensorDesc().GetShape();
--- a/ge/hybrid/executor/hybrid_execution_context.h
+++ b/ge/hybrid/executor/hybrid_execution_context.h
@@ -62,9 +62,9 @@ struct GraphExecutionContext {
  rtStream_t stream = nullptr;
  rtContext_t rt_context = nullptr;
  rtContext_t rt_gen_context = nullptr;
  std::unique_ptr<CallbackManager> callback_manager;
  std::unique_ptr<CallbackManager> callback_manager = nullptr;
  NpuMemoryAllocator *allocator = nullptr;
  mutable std::unique_ptr<HybridProfiler> profiler;
  mutable std::unique_ptr<HybridProfiler> profiler = nullptr;
  DumpProperties dump_properties;
  bool trace_enabled = false;
  bool dump_enabled = false;
--- a/ge/hybrid/executor/hybrid_model_async_executor.cc
+++ b/ge/hybrid/executor/hybrid_model_async_executor.cc
@@ -26,6 +26,7 @@ namespace hybrid {
 namespace {
 const int kDataOutputIndex = 0;
 const size_t kMinimumPiplineStages = 2;
 const int kDefaultLoopCount = 10;
 }
 HybridModelAsyncExecutor::HybridModelAsyncExecutor(HybridModel *model)
    : model_(model), run_flag_(false) {
@@ -45,6 +46,10 @@ void HybridModelAsyncExecutor::SetModelId(uint32_t model_id) {
  model_id_ = model_id;
 }
 void HybridModelAsyncExecutor::SetModelName(const string &model_name) {
  om_name_ = model_name;
 }
 Status HybridModelAsyncExecutor::EnqueueData(const shared_ptr<InputDataWrapper> &data) {
  GE_CHK_STATUS_EXEC(data_inputer_->Push(data), return domi::DATA_QUEUE_ISFULL,
                     "Data queue is full, please call again later, model_id %u ", model_id_);
@@ -80,6 +85,10 @@ Status HybridModelAsyncExecutor::Stop() {
    ret = future_.get();
  }
  if (is_op_debug_reg_) {
    op_debug_register_.UnregisterDebugForStream(stream_);
  }
  if (stream_ != nullptr) {
    GE_CHK_RT(rtStreamDestroy(stream_));
    stream_ = nullptr;
@@ -96,6 +105,7 @@ Status HybridModelAsyncExecutor::Init() {
  executor_ = std::unique_ptr<HybridModelExecutor>(new(std::nothrow) HybridModelExecutor(model_, device_id_, stream_));
  GE_CHECK_NOTNULL(executor_);
  GE_CHK_STATUS_RET(executor_->Init(), "Failed to init hybrid engine");
  GE_CHK_STATUS_RET(DumpOpDebug(),"Dump op debug failed in hybrid engine");
  GELOGI("HybridModel stage nums:%zu", model_->GetRootGraphItem()->NumGroups());
  if (model_->GetRootGraphItem()->NumGroups() >= kMinimumPiplineStages) {
@@ -150,7 +160,7 @@ Status HybridModelAsyncExecutor::RunInternal() {
      GELOGI("HybridModel will execute in pipeline mode");
      auto iter_per_run = std::getenv("ITER_NUM");
      if (iter_per_run) {
        args.num_loops = static_cast<int>(strtol(iter_per_run, nullptr, 10));
        args.num_loops = static_cast<int>(strtol(iter_per_run, nullptr, kDefaultLoopCount));
      }
      ret = pipe_executor_->Execute(args);
    } else {
@@ -250,7 +260,8 @@ Status HybridModelAsyncExecutor::PrepareInputs(const InputData &current_data, Hy
        if (k >= shape.GetDimNum()) {
          break;
        }
        if (shape.GetDim(k) < range[k].first || shape.GetDim(k) > range[k].second) {
        // range[k].second can be -1
        if (shape.GetDim(k) < range[k].first || (range[k].second >= 0 && shape.GetDim(k) > range[k].second)) {
          GELOGE(PARAM_INVALID, "Dim out of range, shape idx = %zu, dim idx = %zu, dim = %ld, range = [%ld, %ld]",
                 input_index, k, shape.GetDim(k), range[k].first, range[k].second);
          return PARAM_INVALID;
@@ -452,8 +463,8 @@ Status HybridModelAsyncExecutor::Execute(const std::vector<DataBuffer> &inputs,
               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;
  }
@@ -502,5 +513,40 @@ Status HybridModelAsyncExecutor::Execute(const vector<GeTensor> &inputs, vector<
  return SUCCESS;
 }
 Status HybridModelAsyncExecutor::DumpOpDebug() {
  const DumpProperties &dump_properties = executor_->GetContext()->dump_properties;
  if (dump_properties.IsOpDebugOpen()) {
    GELOGD("Opdebug is open in hybrid engine");
    uint32_t op_debug_mode = dump_properties.GetOpDebugMode();
    GE_CHK_RT_RET(op_debug_register_.RegisterDebugForStream(stream_, op_debug_mode, data_dumper_));
    is_op_debug_reg_ = true;
    data_dumper_.SetDumpProperties(dump_properties);
    data_dumper_.SetModelName(model_->GetModelName());
    data_dumper_.SetModelId(model_->GetModelId());
    data_dumper_.SetDeviceId(model_->GetDeviceId());
    void *global_step = nullptr;
    TensorValue *varible_global_step = model_->GetVariable(NODE_NAME_GLOBAL_STEP);
    if (varible_global_step != nullptr) {
      global_step = const_cast<void *>(varible_global_step->GetData());
    }
    void *loop_per_iter = nullptr;
    TensorValue *varible_loop_per_iter = model_->GetVariable(NODE_NAME_FLOWCTRL_LOOP_PER_ITER);
    if (varible_loop_per_iter != nullptr) {
      loop_per_iter = const_cast<void *>(varible_loop_per_iter->GetData());
    }
    void *loop_cond = nullptr;
    TensorValue *varible_loop_cond = model_->GetVariable(NODE_NAME_FLOWCTRL_LOOP_COND);
    if (varible_loop_cond != nullptr) {
      loop_cond = const_cast<void *>(varible_loop_cond->GetData());
    }
    data_dumper_.SetLoopAddr(global_step, loop_per_iter, loop_cond);
    GE_CHK_STATUS_RET(data_dumper_.LoadDumpInfo(), "LoadDumpInfo failed in hybrid engine");
    GELOGD("Dump op debug SUCCESS in hybrid engine");
  }
  return SUCCESS;
 }
 }  // namespace hybrid
 }  // namespace ge