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Pre Merge pull request !1941 from 张晓昆/master

pull/1941/MERGE
张晓昆 Gitee 4 years ago
parent
1ae63774b9 99367eb363
commit
f420db6887
24 changed files with 1369 additions and 755 deletions
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  1. +2
    -0
      ge/CMakeLists.txt
  2. +89
    -0
      ge/common/executor.h
  3. +15
    -2
      ge/graph/common/local_context.cc
  4. +17
    -0
      ge/graph/common/local_context.h
  5. +0
    -11
      ge/graph/execute/graph_execute.cc
  6. +0
    -4
      ge/graph/execute/graph_execute.h
  7. +553
    -0
      ge/graph/execute/model_executor.cc
  8. +139
    -0
      ge/graph/execute/model_executor.h
  9. +4
    -5
      ge/graph/load/model_manager/model_manager.cc
  10. +66
    -562
      ge/graph/manager/graph_manager.cc
  11. +15
    -48
      ge/graph/manager/graph_manager.h
  12. +6
    -0
      ge/graph/manager/graph_manager_utils.h
  13. +41
    -3
      ge/session/inner_session.cc
  14. +5
    -0
      ge/session/inner_session.h
  15. +1
    -1
      ge/single_op/task/op_task.h
  16. +4
    -1
      tests/ut/ge/CMakeLists.txt
  17. +11
    -11
      tests/ut/ge/common/datatype_transfer_unittest.cc
  18. +327
    -0
      tests/ut/ge/graph/execute/model_executor_unittest.cc
  19. +48
    -76
      tests/ut/ge/graph/manager/graph_manager_unittest.cc
  20. +16
    -16
      tests/ut/ge/graph/passes/folding_kernel/gather_v2_kernel_unittest.cc
  21. +1
    -1
      tests/ut/ge/graph/passes/mark_node_unknown_shape_pass_unittest.cc
  22. +1
    -1
      tests/ut/ge/graph/passes/multi_batch_clone_pass_unittest.cc
  23. +1
    -1
      tests/ut/ge/graph/passes/subgraph_const_migration_pass_unittest.cc
  24. +7
    -12
      tests/ut/ge/session/inner_session_unittest.cc

+ 2
- 0
ge/CMakeLists.txt View File

@@ -373,6 +373,7 @@ set(TRAIN_SRC_LIST
"opskernel_manager/ops_kernel_builder_manager.cc"
"session/inner_session.cc"
"session/session_manager.cc"
"graph/execute/model_executor.cc"
"single_op/single_op.cc"
"single_op/single_op_manager.cc"
"single_op/single_op_model.cc"
@@ -475,6 +476,7 @@ set(INFER_SRC_LIST
"init/gelib.cc"
"session/inner_session.cc"
"session/session_manager.cc"
"graph/execute/model_executor.cc"
"engine_manager/dnnengine_manager.cc"
"opskernel_manager/ops_kernel_manager.cc"
"opskernel_manager/ops_kernel_builder_manager.cc"


+ 89
- 0
ge/common/executor.h View File

@@ -0,0 +1,89 @@
/**
* Copyright 2021 Huawei Technologies Co., Ltd
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* 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_EXECUTOR_H
#define GE_COMMON_EXECUTOR_H

#include "external/ge/ge_api_types.h"
#include "graph/ge_local_context.h"
#include "graph/manager/graph_manager_utils.h"

namespace ge {
struct RunArgs {
GraphNodePtr graph_node;
GraphId graph_id;
uint64_t session_id;
struct error_message::Context error_context;
std::vector<ge::Tensor> input_tensor;
GeRootModelPtr ge_root_model;
GEThreadLocalContext context;
RunAsyncCallback callback;
};

class Executor {
public:
///
/// @ingroup ge
/// @brief Load mode from graph.
/// @param [in] GeRootModel: root model of graph compiled.
/// @param [in] GraphNode: node of graph.
/// @return Status result of function
///
virtual Status LoadGraph(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node) = 0;

///
/// @ingroup ge
/// @brief Unload mode.
/// @param [in] GeRootModel: root model of graph compiled.
/// @param [in] graph_id: graph identifier.
/// @return Status result of function
///
virtual Status UnloadGraph(const GeRootModelPtr &ge_root_model, uint32_t graph_id) = 0;

///
/// @ingroup ge
/// @brief Push model execution params to queue.
/// @param [in] RunArgs of for model execution.
/// @return Status result of function
///
virtual Status PushGraph(const RunArgs &args) = 0;

///
/// @ingroup ge
/// @brief Run graph for synchronize model.
/// @param [in] graph_node: node of graph.
/// @param [in] graph_id: graph identifier.
/// @param [in] inputs: input data for the graph running.
/// @param [out] outputs: output data of the graph running
/// @return Status result of function
///
virtual Status RunGraph(const GraphNodePtr &graph_node, GraphId graph_id,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs) = 0;

///
/// @ingroup ge
/// @brief Run graph for NN synchronize model.
/// @param [in] graph_node: node of graph.
/// @param [in] graph_id: graph identifier.
/// @param [in] stream: Stream for model running.
/// @param [in] inputs: input data for the graph running.
/// @param [out] outputs: output data of the graph running
/// @return Status result of function
///
virtual Status RunGraphWithStream(const GraphNodePtr &graph_node, GraphId graph_id, rtStream_t stream,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs) = 0;
};
}
#endif // GE_COMMON_EXECUTOR_H

+ 15
- 2
ge/graph/common/local_context.cc View File

@@ -16,13 +16,12 @@

#include "graph/common/local_context.h"

#include "framework/common/ge_inner_error_codes.h"
#include "framework/common/debug/ge_log.h"
#include "framework/omg/omg_inner_types.h"

namespace ge {
namespace {
thread_local OmgContext *omg_context = nullptr;
thread_local OmeContext *ome_context = nullptr;
}

void SetLocalOmgContext(OmgContext &context) {
@@ -37,4 +36,18 @@ OmgContext &GetLocalOmgContext() {
return domi::GetContext();
}
}

void SetLocalOmeContext(OmeContext &context) {
ome_context = &context;
}

OmeContext &GetLocalOmeContext() {
if (ome_context != nullptr) {
return *ome_context;
}

GELOGW("ome_context is nullptr.");
static OmeContext context;
return context;
}
}

+ 17
- 0
ge/graph/common/local_context.h View File

@@ -22,5 +22,22 @@
namespace ge {
void SetLocalOmgContext(OmgContext &context);
OmgContext &GetLocalOmgContext();


struct OmeContext {
bool need_multi_batch = false;
std::string dynamic_node_type;
std::vector<NodePtr> data_nodes;
std::vector<NodePtr> getnext_nosink_nodes;
std::vector<std::string> dynamic_shape_dims;
std::vector<std::pair<std::string, std::vector<int64_t>>> user_input_dims;
std::vector<std::vector<int64_t>> user_real_input_dims;
};

GE_FUNC_VISIBILITY
void SetLocalOmeContext(OmeContext &context);

GE_FUNC_VISIBILITY
OmeContext &GetLocalOmeContext();
} // namespace ge
#endif // GE_GRAPH_COMMON_LOCAL_CONTEXT_H_

+ 0
- 11
ge/graph/execute/graph_execute.cc View File

@@ -31,7 +31,6 @@ GraphExecutor::GraphExecutor()
sync_run_mutex_(nullptr),
condition_(nullptr),
graph_run_listener_(nullptr),
graph_context_(nullptr),
last_graph_id_(UINT32_MAX),
malloc_flag_(false) {}

@@ -79,16 +78,6 @@ Status GraphExecutor::SetCondition(std::mutex *mutex, std::condition_variable *c
return SUCCESS;
}

Status GraphExecutor::SetGraphContext(GraphContextPtr graph_context_ptr) {
if (graph_context_ptr == nullptr) {
REPORT_INNER_ERROR("E19999", "Check param graph_context_ptr nullptr");
GELOGE(GE_GRAPH_PARAM_NULLPTR, "[Check][Param] input param graph_context_ptr is nullptr");
return GE_GRAPH_PARAM_NULLPTR;
}
graph_context_ = graph_context_ptr;
return SUCCESS;
}

Status GraphExecutor::SetDynamicSize(uint32_t model_id, const std::vector<uint64_t> &batch_num, int32_t dynamic_type) {
auto model_manager = ge::ModelManager::GetInstance();
GE_CHECK_NOTNULL(model_manager);


+ 0
- 4
ge/graph/execute/graph_execute.h View File

@@ -60,8 +60,6 @@ class GraphExecutor {

Status SetCondition(std::mutex *mutex, std::condition_variable *cond, std::shared_ptr<GraphModelListener> listener);

Status SetGraphContext(GraphContextPtr graph_context_ptr);

static Status SetDynamicSize(uint32_t model_id, const std::vector<uint64_t> &batch_num, int32_t dynamic_type);

void SetTrainFlag(bool is_train_graph);
@@ -160,8 +158,6 @@ class GraphExecutor {
// Run graph asynchronous call back listener
std::shared_ptr<GraphModelListener> graph_run_listener_;

GraphContextPtr graph_context_;

std::vector<InputOutputDescInfo> outputs_desc_;
GraphId last_graph_id_;



+ 553
- 0
ge/graph/execute/model_executor.cc View File

@@ -0,0 +1,553 @@
/**
* Copyright 2021 Huawei Technologies Co., Ltd
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* 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 "graph/execute/model_executor.h"

#include "graph/ge_context.h"
#include "graph/debug/ge_attr_define.h"
#include "graph/common/ge_call_wrapper.h"
#include "graph/common/local_context.h"
#include "graph/manager/graph_var_manager.h"
#include "graph/utils/tensor_adapter.h"
#include "graph/load/graph_loader.h"
#include "common/math/math_util.h"
#include "common/formats/utils/formats_trans_utils.h"

namespace {
constexpr int32_t kBase = 10;
constexpr uint8_t kNeverLoaded = 0;
}

namespace ge {
///
/// @ingroup ge
/// @brief graph executor init
/// @param [in] options user config params
/// @return Status result of function
///
Status ModelExecutor::Initialize(const map<string, string> &options) {
graph_run_listener_ = MakeShared<GraphModelListener>(sync_run_mutex_, condition_);
if (graph_run_listener_ == nullptr) {
REPORT_CALL_ERROR("E19999", "New GraphModelListener fail");
GELOGE(MEMALLOC_FAILED, "[New][GraphModelListener] failed");
return MEMALLOC_FAILED;
}

train_graph_flag_ = ParseTrainGraphFlag();
thread_run_flag_.store(true);
run_thread_ = std::thread(&ModelExecutor::RunThread, this);

init_flag_ = true;
return SUCCESS;
}

///
/// @ingroup ge
/// @brief graph executor finalize
/// @return Status result of function
///
Status ModelExecutor::Finalize() {
if (!init_flag_) {
GELOGW("ModelExecutor has not been initialized.");
return SUCCESS;
}

StopQueue();
if (run_thread_.joinable()) {
run_thread_.join();
}

if (graph_executor_.FreeExecuteMemory() != SUCCESS) {
GELOGW("Graph executor FreeExecuteMemory failed, resources may not be released correctly.");
}

return SUCCESS;
}

// OPTION_GRAPH_RUN_MODE is supposed to be a session-level option, but it used to be set to global-level in the past.
// If can not parse from session, it can parse from global by GetContext().
bool ModelExecutor::ParseTrainGraphFlag() {
string run_mode;
if (GetContext().GetOption(OPTION_GRAPH_RUN_MODE, run_mode) == SUCCESS && !run_mode.empty()) {
if (GraphRunMode(std::strtol(run_mode.c_str(), nullptr, kBase)) >= TRAIN) {
GELOGI("Graph train flag set.");
return true;
}
}
return false;
}

void ModelExecutor::AddGraphNode(GraphId graph_id, const GraphNodePtr &graph_node) {
std::lock_guard<std::mutex> lock(mutex_);
graph_nodes_.emplace(graph_id, graph_node);
}

void ModelExecutor::RemoveGraphNode(GraphId graph_id) {
std::lock_guard<std::mutex> lock(mutex_);
graph_nodes_.erase(graph_id);
}

///
/// @ingroup ge
/// @brief Load mode for graph.
/// @param [in] GeRootModel: root model of graph compiled.
/// @param [in] GraphNode: node of graph.
/// @return Status result of function
///
Status ModelExecutor::LoadGraph(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node) {
GE_CHECK_NOTNULL(graph_node);
if (ge_root_model == nullptr) {
return SUCCESS;
}

UpdateLocalOmeContext(graph_node);
return graph_node->IsAsync() ? ModelLoadAsync(ge_root_model, graph_node) : ModelLoadSync(ge_root_model, graph_node);
}

///
/// @ingroup ge
/// @brief Unload mode for graph.
/// @param [in] GeRootModel: root model of graph compiled.
/// @param [in] graph_id: graph identifier.
/// @return Status result of function
///
Status ModelExecutor::UnloadGraph(const GeRootModelPtr &ge_root_model, uint32_t graph_id) {
GE_CHECK_NOTNULL(ge_root_model);
rtError_t rt_ret = rtSetDevice(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
GELOGW("[GraphExecutor] rtSetDevice failed, modelId=%u, graphId=%u.", ge_root_model->GetModelId(), graph_id);
return FAILED;
}

RemoveGraphNode(graph_id);
Status ret = UnloadModel(ge_root_model, graph_id);
if (ret != SUCCESS) {
GELOGW("[GraphExecutor] unload model failed, graph_id=%u.", graph_id);
}
rt_ret = rtDeviceReset(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
GELOGW("[GraphExecutor] rtDeviceReset failed, graphId=%u.", graph_id);
}

return ret;
}

Status ModelExecutor::UnloadModel(const GeRootModelPtr &ge_root_model, uint32_t graph_id) {
GE_CHECK_NOTNULL(ge_root_model);
for (size_t i = 0; i < ge_root_model->GetAllModelId().size(); ++i) {
uint32_t model_id = ge_root_model->GetAllModelId()[i];
GELOGI("Unload model %u.", model_id);
Status ret = GraphLoader::UnloadModel(model_id);
if (ret != SUCCESS) {
GELOGE(ret, "[GraphExecutor] unload model failed, modelId=%u, graphId=%u.", model_id, graph_id);
return ret;
}
}
return SUCCESS;
}

void ModelExecutor::StopQueue() {
thread_run_flag_.store(false);
run_args_q_.Stop();
}

void ModelExecutor::ReturnError(RunAsyncCallback callback, Status ret, const string &log) {
StopQueue();
GELOGE(ret, "%s.", log.c_str());
std::vector<ge::Tensor> outputs;
callback(ret, outputs);
}

void ModelExecutor::UpdateLocalOmeContext(const GraphNodePtr &graph_node) {
std::lock_guard<std::mutex> lock(mutex_);
SetLocalOmeContext(graph_node->GetOmeContext());
}

///
/// @ingroup ge
/// @brief Push model execution params to queue.
/// @param [in] RunArgs of for model execution.
/// @return Status result of function
///
Status ModelExecutor::PushGraph(const RunArgs &args) {
return run_args_q_.Push(args) ? SUCCESS : FAILED;
}

void ModelExecutor::RunThread() {
ErrorManager::GetInstance().SetStage(error_message::kModelExecute, error_message::kModelExecute);
if (prctl(PR_SET_NAME, ("GE_Run")) != 0) {
GELOGW("Set thread name failed.");
}

RunArgs args;
while (thread_run_flag_) {
if (!run_args_q_.Pop(args)) {
continue;
}

GELOGI("[RunThread] A new loop start, graph_id:%u.", args.graph_id);
ErrorManager::GetInstance().SetErrorContext(args.error_context);
GetContext().SetSessionId(args.session_id);
GetThreadLocalContext() = args.context;
UpdateLocalOmeContext(args.graph_node);

// parse inputs.dims to vector<vector<uint64_t>> dynamic_dims
Status ret = ParseInputsDims(args.input_tensor);
if (ret != SUCCESS) {
ReturnError(args.callback, ret, "ParseInputsDims failed, thread exit.");
args.graph_node->Unlock();
return;
}

args.graph_node->UpdateLoadFlag();
if (!args.graph_node->GetLoadFlag()) {
ErrorManager::GetInstance().SetStage(error_message::kModelLoad, error_message::kModelLoad);
args.ge_root_model->SetTrainFlag(train_graph_flag_);
ret = ModelLoadAsync(args.ge_root_model, args.graph_node);
if (ret != SUCCESS || args.ge_root_model == nullptr) {
StopQueue();
ReturnError(args.callback, ret, "LoadGraphAsync failed, thread exit.");
args.graph_node->Unlock();
return;
}
// control the times of graph loading in multi-thread scenario
args.graph_node->DecreaseLoadCount();
args.graph_node->IncreaseLoadRecord();

args.graph_node->SetLoadFlag(true);
GELOGI("LoadGraph[%u], model[%u] success and set LoadFlag to true.", args.graph_node->GetGraphId(),
args.ge_root_model->GetModelId());
}

ErrorManager::GetInstance().SetStage(error_message::kModelExecute, error_message::kModelExecute);
if (train_graph_flag_) {
graph_executor_.SetTrainFlag(train_graph_flag_);
}

ret = graph_executor_.ExecuteGraphAsync(args.graph_id, args.graph_node->GetGeRootModel(),
args.input_tensor, args.callback);
args.graph_node->SetRunFlag(false);
if (ret != SUCCESS) {
ReturnError(args.callback, ret, "ExecuteGraphAsync failed, thread exit.");
args.graph_node->Unlock();
return;
}
args.graph_node->Unlock();
GELOGI("[GraphExecutor] Run graph async success, graph_id=%u.", args.graph_id);
}
}

///
/// @ingroup ge
/// @brief Run graph for synchronize model.
/// @param [in] graph_node: node of graph.
/// @param [in] graph_id: graph identifier.
/// @param [in] inputs: input data for the graph running.
/// @param [out] outputs: output data of the graph running
/// @return Status result of function
///
Status ModelExecutor::RunGraph(const GraphNodePtr &graph_node, GraphId graph_id,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs) {
Status ret = graph_executor_.SetCondition(&sync_run_mutex_, &condition_, graph_run_listener_);
if (ret != SUCCESS) {
GELOGE(GE_GRAPH_RUNGRAPH_FAILED, "[Set][Condition] failed, graph_id = %u.", graph_id);
graph_node->SetRunFlag(false);
return GE_GRAPH_RUNGRAPH_FAILED;
}

if (train_graph_flag_) {
graph_executor_.SetTrainFlag(train_graph_flag_);
}
ret = graph_executor_.ExecuteGraph(graph_id, graph_node->GetGeRootModel(), inputs, outputs);

graph_node->SetRunFlag(false);
if (ret != SUCCESS) {
GELOGE(ret, "[Execute][Graph] failed, graph_id = %u.", graph_id);
return ret;
}
return SUCCESS;
}

///
/// @ingroup ge
/// @brief Run graph for NN synchronize model.
/// @param [in] graph_node: node of graph.
/// @param [in] graph_id: graph identifier.
/// @param [in] stream: Stream for model running.
/// @param [in] inputs: input data for the graph running.
/// @param [out] outputs: output data of the graph running
/// @return Status result of function
///
Status ModelExecutor::RunGraphWithStream(const GraphNodePtr &graph_node, GraphId graph_id, rtStream_t stream,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs) {
auto ret = graph_executor_.SetCondition(&sync_run_mutex_, &condition_, graph_run_listener_);
if (ret != SUCCESS) {
GELOGE(GE_GRAPH_RUNGRAPH_FAILED, "[Set][Condition] failed, graph id = %u, stream = %p.", graph_id, stream);
graph_node->SetRunFlag(false);
return GE_GRAPH_RUNGRAPH_FAILED;
}

ret = graph_executor_.ExecuteGraphWithStream(graph_id, stream, graph_node->GetGeRootModel(), inputs, outputs);
graph_node->SetRunFlag(false);
graph_node->SetIsSpecificStream(false);
if (ret != SUCCESS) {
GELOGE(ret, "[Execute][Graph] With Stream failed, graph id = %u, stream = %p.", graph_id, stream);
return ret;
}
GELOGI("[Run][GraphWithStreamAsync] run graph success, graph id = %u, stream = %p.", graph_id, stream);
return SUCCESS;
}

Status ModelExecutor::ModelLoadSync(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node) {
ge_root_model->SetIsSpecificStream(graph_node->IsSpecificStream());
return ModelLoad(ge_root_model, graph_node, graph_run_listener_);
}

Status ModelExecutor::ModelLoadAsync(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node) {
auto listener = MakeShared<RunAsyncListener>();
GE_CHECK_NOTNULL(listener);
return ModelLoad(ge_root_model, graph_node, listener);
}

Status ModelExecutor::ModelLoad(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node,
const std::shared_ptr<ModelListener> &listener) {
ge_root_model->SetTrainFlag(train_graph_flag_);
bool is_unknown_shape = false;
GE_CHK_STATUS_RET(ge_root_model->CheckIsUnknownShape(is_unknown_shape));
if (!is_unknown_shape) {
if (getenv(kEnvGeuseStaticMemory) != nullptr) {
GELOGI("[LoadGraph] GE_USE_STATIC_MEMORY is seted.");
} else {
auto root_graph = ge_root_model->GetRootGraph();
GE_CHECK_NOTNULL(root_graph);
auto name_to_model = ge_root_model->GetSubgraphInstanceNameToModel();
GeModelPtr ge_model = name_to_model[root_graph->GetName()];
GE_CHK_STATUS_RET(CheckAndReleaseMemory(ge_model, graph_node));
}
}
GE_TIMESTAMP_START(LoadModelOnline);
uint32_t model_id = INVALID_MODEL_ID;
Status ret = GraphLoader::LoadModelOnline(model_id, ge_root_model, listener);
GE_TIMESTAMP_EVENT_END(LoadModelOnline, "GraphLoader::LoadModelOnline");
if (ret != SUCCESS) {
GELOGE(ret, "[Load][ModelOnline] Failed, model_id:%u", model_id);
graph_node->SetRunFlag(false);
return ret;
}
graph_node->SetLoadFlag(true);
ge_root_model->SetModelId(model_id);
graph_node->SetGeRootModel(ge_root_model);
AddGraphNode(graph_node->GetGraphId(), graph_node);
return SUCCESS;
}

void ModelExecutor::ReleaseMemory(const GeModelPtr &ge_model, const GraphNodePtr &graph_node,
const std::vector<uint32_t> &model_ids, uint32_t graph_id, uint64_t session_id) {
rtError_t rt_ret = rtSetDevice(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
REPORT_CALL_ERROR("E19999", "Call rtSetDevice failed, device_id:%u", GetContext().DeviceId());
GELOGE(RT_FAILED, "[Call][RtSetDevice] failed, device_id=%u.", GetContext().DeviceId());
return;
}
for (auto model_id : model_ids) {
uint64_t max_memory_size = 0;
Status result = GraphLoader::GetMaxUsedMemory(model_id, max_memory_size);
if (result != SUCCESS) {
continue;
}
GELOGI("try to UnloadGraph[%u], model[%u] which MaxUsedMemory[%lu].", graph_id, model_id, max_memory_size);
if (model_ids.size() > 1) {
result = ge_model->GetSessionId(model_id, session_id);
if (result != SUCCESS) {
GELOGW("[GraphExecutor:] get session failed when dynamic memory, modelId=%u, graphId=%u.", model_id,
graph_id);
continue;
}
}
result = GraphLoader::DestroyAicpuKernel(session_id, model_id, 0);
if (result != SUCCESS) {
GELOGW("[GraphExecutor:] destroy aicpu kernel failed when dynamic memory, modelId=%u, graphId=%u.", model_id,
graph_id);
}
result = GraphLoader::UnloadModel(model_id);
if (result != SUCCESS) {
GELOGW("[GraphExecutor:] unload model failed, modelId=%u, graphId=%u.", model_id, graph_id);
}
GELOGI("UnloadGraph[%u], model[%u] success.", graph_id, model_id);
}
graph_node->SetLoadFlag(false);
// Allow model to be loaded agagin without adding graph again
graph_node->SetLoadCount(graph_node->GetLoadRecord());
graph_node->SetLoadRecord(kNeverLoaded);
GeRootModelPtr ge_root_model = graph_node->GetGeRootModel();
if (ge_root_model == nullptr) {
GELOGW("ge_root_model is null, graph_id:%u", graph_id);
return;
}
ge_root_model->ClearAllModelId();
rt_ret = rtDeviceReset(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
REPORT_CALL_ERROR("E19999", "Call rtDeviceReset failed, device_id:%u", GetContext().DeviceId());
GELOGE(RT_FAILED, "[Call][RtDeviceReset] failed, device_id:%u.", GetContext().DeviceId());
return;
}
}

Status ModelExecutor::CheckAndReleaseMemory(const GeModelPtr &ge_model, const GraphNodePtr &graph_node) {
GELOGI("graph_id[%u]", graph_node->GetGraphId());
int64_t free_memory = 0;
Status result = GraphLoader::GetMemoryInfo(free_memory);
if (result != SUCCESS) {
return result;
}

int64_t value = 0;
int64_t memory_size = AttrUtils::GetInt(ge_model, ATTR_MODEL_MEMORY_SIZE, value) ? value : 0;
int64_t weight_size = AttrUtils::GetInt(ge_model, ATTR_MODEL_WEIGHT_SIZE, value) ? value : 0;
int64_t session_id = AttrUtils::GetInt(ge_model, MODEL_ATTR_SESSION_ID, value) ? value : 0;

GELOGI("Graph[%u] need memory_size[%ld], weight_size[%ld], Device[%u] free_memory_size[%ld]",
graph_node->GetGraphId(), memory_size, weight_size, GetContext().DeviceId(), free_memory);
if (CheckInt64AddOverflow(memory_size, weight_size) != SUCCESS) {
REPORT_INNER_ERROR("E19999", "memory_size:%ld and weight_size:%ld will overflow after add, check invalid",
memory_size, weight_size);
GELOGE(INTERNAL_ERROR, "[Check][Param] memory_size:%ld and weight_size:%ld will overflow after add",
memory_size, weight_size);
return INTERNAL_ERROR;
}
if (free_memory >= (memory_size + weight_size)) {
return SUCCESS;
}

std::lock_guard<std::mutex> lock(mutex_);
for (const auto &it : graph_nodes_) {
auto graph_id = it.second->GetGraphId();
auto model = it.second->GetGeRootModel();
if (model == nullptr) {
continue;
}
auto model_id = model->GetModelId();
auto model_ids = model->GetAllModelId();
// unload model not release
bool is_unknown_shape = false;
GE_CHK_STATUS_RET(model->CheckIsUnknownShape(is_unknown_shape));
if (is_unknown_shape) {
GELOGD("model_id[%u] graph_id[%u] is unknown model, not release memory", model_id, graph_id);
continue;
}
// not loaded,no need unload
if (!it.second->GetLoadFlag()) {
GELOGI("CheckAndReleaseMemory graph[%u] has not been loaded.", graph_id);
continue;
}
ReleaseMemory(ge_model, it.second, model_ids, graph_id, static_cast<uint64_t>(session_id));
}

return SUCCESS;
}

void ModelExecutor::ParseInputsDimsForData(const std::vector<ge::Tensor> &input_tensor) {
GELOGD("Start parse input dims from data.");
for (size_t i = 0; i < input_tensor.size(); ++i) {
const TensorDesc &tensor_desc = input_tensor[i].GetTensorDesc();
const Shape &shape = tensor_desc.GetShape();
const auto &shape_dims = shape.GetDims();
GELOGD("Input tensor dims is %s.", formats::JoinToString(shape_dims).c_str());
GetLocalOmeContext().user_real_input_dims.emplace_back(shape_dims);
}
}

Status ModelExecutor::ParseInputsDimsForGetNextNoSinkAndData(const vector<NodePtr> &dynamic_nodes,
const std::vector<ge::Tensor> &input_tensor) {
GELOGD("Start parse inputs dims when coexist data and getnext sink.");
for (size_t i = 0; i < dynamic_nodes.size(); ++i) {
auto op_desc = dynamic_nodes.at(i)->GetOpDesc();
if (op_desc == nullptr) {
continue;
}
GeAttrValue::INT index = 0;
if (!(AttrUtils::GetInt(op_desc, ATTR_NAME_INDEX, index))) {
REPORT_CALL_ERROR("E19999", "Get Attr:%s from op:%s(%s) fail", ATTR_NAME_INDEX.c_str(),
op_desc->GetName().c_str(), op_desc->GetType().c_str());
GELOGE(PARAM_INVALID, "[Get][Attr] %s from op:%s(%s) fail", ATTR_NAME_INDEX.c_str(),
op_desc->GetName().c_str(), op_desc->GetType().c_str());
return PARAM_INVALID;
}
if (static_cast<size_t>(index) > input_tensor.size()) {
REPORT_INNER_ERROR("E19999", "Attr:%s in op:%s(%s) value:%ld > param input_tensor.size:%zu, "
"check invalid", ATTR_NAME_INDEX.c_str(),
op_desc->GetName().c_str(), op_desc->GetType().c_str(),
index, input_tensor.size());
GELOGE(PARAM_INVALID, "[Check][Param] Attr:%s in op:%s(%s) value:%ld > param input_tensor.size:%zu",
ATTR_NAME_INDEX.c_str(), op_desc->GetName().c_str(), op_desc->GetType().c_str(),
index, input_tensor.size());
return PARAM_INVALID;
}

const TensorDesc &tensor_desc = input_tensor[i].GetTensorDesc();
const Shape &shape = tensor_desc.GetShape();
const auto &shape_dims = shape.GetDims();
GELOGI("Shape dims of %zu data is %s.", index, formats::JoinToString(shape_dims).c_str());
GetLocalOmeContext().user_real_input_dims.emplace_back(std::move(shape_dims));
}
return SUCCESS;
}

Status ModelExecutor::ParseInputsDims(const std::vector<ge::Tensor> &input_tensor) {
GELOGI("Start parse input dims of %zu input tensor.", input_tensor.size());
GetLocalOmeContext().user_real_input_dims.clear();
if (GetLocalOmeContext().dynamic_node_type.empty()) {
return SUCCESS;
}

const vector<NodePtr> &data_nodes = GetLocalOmeContext().data_nodes;
const vector<NodePtr> &getnext_nosink_nodes = GetLocalOmeContext().getnext_nosink_nodes;
GELOGD("Data nodes count is %zu, getnext nosink nodes count is %zu.", data_nodes.size(),
getnext_nosink_nodes.size());
if (GetLocalOmeContext().dynamic_node_type == DATA) {
if (getnext_nosink_nodes.empty()) {
// just data or data+getnext_sink
ParseInputsDimsForData(input_tensor);
} else {
// data+getnext_nosink, but only need to get shape_dims of data
if (ParseInputsDimsForGetNextNoSinkAndData(data_nodes, input_tensor) != SUCCESS) {
GELOGE(PARAM_INVALID, "[Parse][Dims] from data failed, when data coexist with getnext nosink.");
return PARAM_INVALID;
}
}
} else {
if (getnext_nosink_nodes.empty()) {
// just getnext_sink or getnext_sink+data, need to get shape_dims from aicpu op
GELOGI("Need to get dims from aicpu op: GETDYNAMICDIMS.");
return SUCCESS;
} else {
if (data_nodes.empty()) {
// just getnext_nosink
ParseInputsDimsForData(input_tensor);
} else {
// getnext_nosink + data, but only need to get shape_dims of getnext_nosink
if (ParseInputsDimsForGetNextNoSinkAndData(getnext_nosink_nodes, input_tensor) != SUCCESS) {
GELOGE(PARAM_INVALID, "[Parse][Dims] from getnext nosink failed, when data coexist with getnext nosink");
return PARAM_INVALID;
}
}
}
}

GELOGI("Parse %zu inputs dims success.", GetLocalOmeContext().user_real_input_dims.size());
return SUCCESS;
}
} // namespace ge

+ 139
- 0
ge/graph/execute/model_executor.h View File

@@ -0,0 +1,139 @@
/**
* Copyright 2021 Huawei Technologies Co., Ltd
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* 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_GRAPH_EXECUTE_MODEL_EXECUTOR_H
#define GE_GRAPH_EXECUTE_MODEL_EXECUTOR_H

#include <thread>

#include "common/executor.h"
#include "graph/execute/graph_execute.h"

namespace ge {
class ModelExecutor : public Executor {
public:
///
/// @ingroup ge
/// @brief graph executor init
/// @param [in] options user config params
/// @return Status result of function
///
Status Initialize(const map<string, string> &options);

///
/// @ingroup ge
/// @brief graph executor finalize
/// @return Status result of function
///
Status Finalize();

///
/// @ingroup ge
/// @brief Load mode for graph.
/// @param [in] GeRootModel: root model of graph compiled.
/// @param [in] GraphNode: node of graph.
/// @return Status result of function
///
Status LoadGraph(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node);

///
/// @ingroup ge
/// @brief Unload mode for graph.
/// @param [in] GeRootModel: root model of graph compiled.
/// @param [in] graph_id: graph identifier.
/// @return Status result of function
///
Status UnloadGraph(const GeRootModelPtr &ge_root_model, uint32_t graph_id);

///
/// @ingroup ge
/// @brief Push model execution params to queue.
/// @param [in] RunArgs of for model execution.
/// @return Status result of function
///
Status PushGraph(const RunArgs &args);

///
/// @ingroup ge
/// @brief Run graph for synchronize model.
/// @param [in] graph_node: node of graph.
/// @param [in] graph_id: graph identifier.
/// @param [in] inputs: input data for the graph running.
/// @param [out] outputs: output data of the graph running
/// @return Status result of function
///
Status RunGraph(const GraphNodePtr &graph_node, GraphId graph_id,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs);

///
/// @ingroup ge
/// @brief Run graph for NN synchronize model.
/// @param [in] graph_node: node of graph.
/// @param [in] graph_id: graph identifier.
/// @param [in] stream: Stream for model running.
/// @param [in] inputs: input data for the graph running.
/// @param [out] outputs: output data of the graph running
/// @return Status result of function
///
Status RunGraphWithStream(const GraphNodePtr &graph_node, GraphId graph_id, rtStream_t stream,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs);

private:
bool ParseTrainGraphFlag();

void AddGraphNode(GraphId graph_id, const GraphNodePtr &graph_node);
void RemoveGraphNode(GraphId graph_id);

Status ModelLoadSync(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node);
Status ModelLoadAsync(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node);
Status ModelLoad(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node,
const std::shared_ptr<ModelListener> &listener);

Status UnloadModel(const GeRootModelPtr &ge_root_model, uint32_t graph_id);

void ReleaseMemory(const GeModelPtr &ge_model, const GraphNodePtr &graph_node, const std::vector<uint32_t> &model_ids,
uint32_t graph_id, uint64_t session_id);
Status CheckAndReleaseMemory(const GeModelPtr &ge_model, const GraphNodePtr &graph_node);

void UpdateLocalOmeContext(const GraphNodePtr &graph_node);

void RunThread();
void StopQueue();
void ReturnError(RunAsyncCallback callback, Status ret, const string &log);

void ParseInputsDimsForData(const std::vector<ge::Tensor> &input_tensor);
Status ParseInputsDimsForGetNextNoSinkAndData(const vector<NodePtr> &dynamic_nodes,
const std::vector<ge::Tensor> &input_tensor);
Status ParseInputsDims(const std::vector<ge::Tensor> &input_tensor);

bool init_flag_{false};
bool train_graph_flag_{false};
GraphExecutor graph_executor_;

std::mutex mutex_;
std::map<GraphId, GraphNodePtr> graph_nodes_;

std::thread run_thread_;
std::atomic_bool thread_run_flag_{false};
BlockingQueue<RunArgs> run_args_q_;

// for run graph synchronous return
std::mutex sync_run_mutex_;
std::condition_variable condition_;
// run graph synchronization call back listener
std::shared_ptr<GraphModelListener> graph_run_listener_;
};
}
#endif // GE_GRAPH_EXECUTE_MODEL_EXECUTOR_H

+ 4
- 5
ge/graph/load/model_manager/model_manager.cc View File

@@ -513,8 +513,7 @@ Status ModelManager::GetCurDynamicDims(const vector<vector<int64_t>> &user_real_
}
GELOGD("Cur dynamic dims is %s.", formats::JoinToString(cur_dynamic_dims).c_str());
bool cur_dynamic_dims_valid = false;
std::vector<std::string> shape_strs = ge::StringUtils::Split(GetLocalOmgContext().dynamic_dims, ';');
for (auto dynamic_dim : shape_strs) {
for (auto dynamic_dim : GetLocalOmeContext().dynamic_shape_dims) {
if (dynamic_dim == formats::JoinToString(cur_dynamic_dims)) {
cur_dynamic_dims_valid = true;
break;
@@ -556,10 +555,10 @@ Status ModelManager::DataInputTensor(uint32_t model_id, const std::vector<ge::Te
input_data.shapes.emplace_back(tensor_desc.GetShape().GetDims());
input_data.blobs.push_back(data);
}
if (!GetLocalOmgContext().user_input_dims.empty() && GetLocalOmgContext().need_multi_batch) {
if (!GetLocalOmeContext().user_input_dims.empty() && GetLocalOmeContext().need_multi_batch) {
std::vector<int32_t> cur_dynamic_dims;
if (!GetLocalOmgContext().user_real_input_dims.empty()) {
if (GetCurDynamicDims(GetLocalOmgContext().user_real_input_dims, GetLocalOmgContext().user_input_dims,
if (!GetLocalOmeContext().user_real_input_dims.empty()) {
if (GetCurDynamicDims(GetLocalOmeContext().user_real_input_dims, GetLocalOmeContext().user_input_dims,
cur_dynamic_dims) != SUCCESS) {
GELOGE(INTERNAL_ERROR, "[Get][CurDynamicDims] [Train_Dynamic] Failed to Parse real_dynamic_dims.");
return INTERNAL_ERROR;


+ 66
- 562
ge/graph/manager/graph_manager.cc View File

@@ -129,8 +129,6 @@ const uint32_t kInitGraphCount = 1;
const uint32_t kNotAdded = 0;
const uint32_t kStartAdd = 1;
const uint32_t kDoneAdded = 2;
const uint32_t kNeverLoaded = 0;
const size_t kAlignment = 64;

bool IsTailingOptimization() {
string is_tailing_optimization_option;
@@ -164,26 +162,12 @@ ge::Status CheckFpCeilingMode() {
} // namespace

namespace ge {
GraphManager::GraphManager()
: thread_run_flag_(false),
graph_run_listener_(nullptr),
init_flag_(false) {
}

Status GraphManager::Initialize(const std::map<string, string> &options) {
Status GraphManager::Initialize(const std::map<string, string> &options, Executor *executor) {
ErrorManager::GetInstance().SetStage(error_message::kInitialize, error_message::kOther);
if (init_flag_) {
GELOGW("[Initialize] GraphManager already initialized.");
return SUCCESS;
}

// malloc
graph_run_listener_ = MakeShared<GraphModelListener>(sync_run_mutex_, condition_);
if (graph_run_listener_ == nullptr) {
REPORT_CALL_ERROR("E19999", "New GraphModelListener fail");
GELOGE(MEMALLOC_FAILED, "[New][GraphModelListener] failed");
return MEMALLOC_FAILED;
}
// graph context
graph_context_ = MakeShared<GraphContext>();
if (graph_context_ == nullptr) {
@@ -211,31 +195,18 @@ Status GraphManager::Initialize(const std::map<string, string> &options) {
return ret;
}

graph_map_.clear();
cache_helper_map_.clear();
graph_id_to_add_graph_cond_.clear();
graph_count_.clear();
executor_ = executor;
init_flag_ = true;

thread_run_flag_ = true;
prerun_thread_ = std::thread(GraphManager::PreRunThread, this);
run_thread_ = std::thread(GraphManager::RunThread, this);
prerun_thread_ = std::thread(&GraphManager::PreRunThread, this);

return SUCCESS;
}

Status GraphManager::UnloadModel(GeRootModelPtr ge_root_model, uint32_t graph_id) {
Status ret = SUCCESS;
for (size_t i = 0; i < ge_root_model->GetAllModelId().size(); ++i) {
uint32_t model_id = ge_root_model->GetAllModelId()[i];
GELOGI("Unload model %u.", model_id);
ret = GraphLoader::UnloadModel(model_id);
if (ret != SUCCESS) {
GELOGW("[GraphManager] unload model failed, modelId=%u, graphId=%u.", model_id, graph_id);
return ret;
}
}
return ret;
GE_CHECK_NOTNULL(executor_);
return executor_->UnloadGraph(ge_root_model, graph_id);
}

Status GraphManager::Finalize() {
@@ -244,23 +215,13 @@ Status GraphManager::Finalize() {
return SUCCESS;
}

if (graph_executor_.FreeExecuteMemory() != SUCCESS) {
GELOGW("Graph executor FreeExecuteMemory failed, resources may not be released correctly.");
}

StopQueue(this);

StopQueue();
if (prerun_thread_.joinable()) {
prerun_thread_.join();
}
if (run_thread_.joinable()) {
run_thread_.join();
}

// check graph whether running or not
Status unload_model_ret = SUCCESS;
Status ret;
rtError_t rt_ret;
for (auto iter = graph_map_.begin(); iter != graph_map_.end(); ++iter) {
GraphNodePtr graph_node = iter->second;
if (graph_node->GetRunFlag()) {
@@ -271,22 +232,10 @@ Status GraphManager::Finalize() {
// unload model
auto ge_root_model = graph_node->GetGeRootModel();
if (ge_root_model != nullptr && ge_root_model->GetModelId() != INVALID_MODEL_ID && graph_node->GetLoadFlag()) {
rt_ret = rtSetDevice(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
GELOGW("[GraphManager] rtSetDevice failed, modelId=%u, graphId=%u.", ge_root_model->GetModelId(), iter->first);
unload_model_ret = FAILED;
continue;
}
ret = UnloadModel(ge_root_model, iter->first);
Status ret = UnloadModel(ge_root_model, iter->first);
if (ret != SUCCESS) {
GELOGW("[GraphManager] unload model failed, graph_id=%u.", iter->first);
unload_model_ret = ret;
}
rt_ret = rtDeviceReset(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
GELOGW("[GraphManager] rtDeviceReset failed, graphId=%u.", iter->first);
unload_model_ret = FAILED;
continue;
GELOGW("[GraphManager] unload model failed, graph_id=%u.", iter->first);
}
}

@@ -1122,12 +1071,7 @@ Status GraphManager::StartForRunGraph(const GraphNodePtr &graph_node, const std:
return ret;
}
}
ErrorManager::GetInstance().SetStage(error_message::kModelLoad, error_message::kModelLoad);
if (!graph_node->IsAsync()) {
ret = LoadGraph(ge_root_model, graph_node);
} else {
ret = LoadGraphAsync(ge_root_model, graph_node);
}
ret = LoadGraph(ge_root_model, graph_node);
if (ret != SUCCESS) {
GELOGE(ret, "[Load][Graph] Failed, graph_id:%u.", graph_node->GetGraphId());
return ret;
@@ -1135,13 +1079,8 @@ 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(error_message::kModelLoad, error_message::kModelLoad);
GeRootModelPtr ge_root_model_ptr = graph_node->GetGeRootModel();
if (!graph_node->IsAsync()) {
ret = LoadGraph(ge_root_model_ptr, graph_node);
} else {
ret = LoadGraphAsync(ge_root_model_ptr, graph_node);
}
ret = LoadGraph(ge_root_model, graph_node);
if (ret != SUCCESS) {
GELOGE(ret, "[Load][Graph] Failed, graph_id:%u.", graph_node->GetGraphId());
return ret;
@@ -1149,40 +1088,16 @@ Status GraphManager::StartForRunGraph(const GraphNodePtr &graph_node, const std:
}
return ret;
}

Status GraphManager::LoadGraph(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node) {
GELOGI("[LoadGraph] run_graph_flag[%d], graph_id[%u]", options_.run_graph_flag, graph_node->GetGraphId());
if (options_.run_graph_flag && ge_root_model != nullptr) {
ge_root_model->SetTrainFlag(GetTrainFlag());
// synchronization run graph with model
std::shared_ptr<GraphModelListener> model_listener = GetModelListener();
ModelIdInfo model_id_info;
bool is_unknown_shape = false;
GE_CHK_STATUS_RET(ge_root_model->CheckIsUnknownShape(is_unknown_shape));
if (!is_unknown_shape) {
if (getenv(kEnvGeuseStaticMemory) != nullptr) {
GELOGI("[LoadGraph] GE_USE_STATIC_MEMORY is seted.");
} else {
auto root_graph = ge_root_model->GetRootGraph();
GE_CHECK_NOTNULL(root_graph);
auto name_to_model = ge_root_model->GetSubgraphInstanceNameToModel();
GeModelPtr ge_model = name_to_model[root_graph->GetName()];
GE_CHK_STATUS_RET(CheckAndReleaseMemory(ge_model, graph_node));
}
}
ge_root_model->SetIsSpecificStream(graph_node->IsSpecificStream());
GE_TIMESTAMP_START(LoadGraph);
Status ret = GraphLoader::LoadModelOnline(model_id_info.model_id, ge_root_model, model_listener);
GE_TIMESTAMP_EVENT_END(LoadGraph, "GraphManager::LoadGraph");
if (ret != SUCCESS) {
GELOGE(ret, "[Load][Model] failed, ret:%d", ret);
graph_node->SetRunFlag(false);
return ret;
}
graph_node->SetLoadFlag(true);
ge_root_model->SetModelId(model_id_info.model_id);
graph_node->SetGeRootModel(ge_root_model);
if (!options_.run_graph_flag) {
return SUCCESS;
}
return SUCCESS;

ErrorManager::GetInstance().SetStage(error_message::kModelLoad, error_message::kModelLoad);
GE_CHECK_NOTNULL(executor_);
return executor_->LoadGraph(ge_root_model, graph_node);
}

Status GraphManager::LoadFromCache(const GraphNodePtr &graph_node, const ModelCacheHelperPtr &cache_helper,
@@ -1272,45 +1187,14 @@ Status GraphManager::SaveCacheAfterBuild(uint32_t graph_id, ge::ComputeGraphPtr

Status GraphManager::InnerRunGraph(GraphNodePtr &graph_node, const GraphId &graph_id,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs) {
Status ret = graph_executor_.SetCondition(&sync_run_mutex_, &condition_, graph_run_listener_);
if (ret != SUCCESS) {
GELOGE(GE_GRAPH_RUNGRAPH_FAILED, "[Set][Condition] failed, graph_id = %u.", graph_id);
graph_node->SetRunFlag(false);
return GE_GRAPH_RUNGRAPH_FAILED;
}

if (GetTrainFlag()) {
GE_CHK_STATUS_RET(graph_executor_.SetGraphContext(GetGraphContext()));
graph_executor_.SetTrainFlag(options_.train_graph_flag);
}
ret = graph_executor_.ExecuteGraph(graph_id, graph_node->GetGeRootModel(), inputs, outputs);

graph_node->SetRunFlag(false);
if (ret != SUCCESS) {
GELOGE(ret, "[Execute][Graph] failed, graph_id = %u.", graph_id);
return ret;
}
return SUCCESS;
GE_CHECK_NOTNULL(executor_);
return executor_->RunGraph(graph_node, graph_id, inputs, outputs);
}

Status GraphManager::InnerRunGraphWithStream(GraphNodePtr &graph_node, const GraphId &graph_id, rtStream_t stream,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs) {
auto ret = graph_executor_.SetCondition(&sync_run_mutex_, &condition_, graph_run_listener_);
if (ret != SUCCESS) {
GELOGE(GE_GRAPH_RUNGRAPH_FAILED, "[Set][Condition] failed, graph id = %u, stream = %p.", graph_id, stream);
graph_node->SetRunFlag(false);
return GE_GRAPH_RUNGRAPH_FAILED;
}

ret = graph_executor_.ExecuteGraphWithStream(graph_id, stream, graph_node->GetGeRootModel(), inputs, outputs);
graph_node->SetRunFlag(false);
graph_node->SetIsSpecificStream(false);
if (ret != SUCCESS) {
GELOGE(ret, "[Execute][Graph] With Stream failed, graph id = %u, stream = %p.", graph_id, stream);
return ret;
}
GELOGI("[Run][GraphWithStreamAsync] run graph success, graph id = %u, stream = %p.", graph_id, stream);
return SUCCESS;
GE_CHECK_NOTNULL(executor_);
return executor_->RunGraphWithStream(graph_node, graph_id, stream, inputs, outputs);
}

Status GraphManager::RunGraphWithStreamAsync(const GraphId &graph_id, rtStream_t stream, uint64_t session_id,
@@ -1665,38 +1549,18 @@ Status GraphManager::RemoveGraph(const GraphId &graph_id) {

std::lock_guard<std::mutex> lock(unload_model_mutex_);

Status middle_ret;
rtError_t rt_ret;
var_acc_ctrl_.RemoveGraph(graph_id);
RemoveGraphNode(graph_id);

RemoveModelCacheHelper(graph_id);

auto ge_root_model = graph_node->GetGeRootModel();
if (CheckModelLoad(ge_root_model, graph_node->GetLoadFlag())) {
rt_ret = rtSetDevice(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
REPORT_CALL_ERROR("E19999", "Call rtSetDevice failed, device_id:%u, graph_id:%u",
GetContext().DeviceId(), graph_id);
GELOGE(RT_FAILED, "[Call][RtSetDevice] failed, modelId=%u, graphId=%u.", ge_root_model->GetModelId(),
graph_id);
return FAILED;
}
// same graph may be added for several times, different models were created separately,
// unload them respectively.
middle_ret = UnloadModel(ge_root_model, graph_id);
Status middle_ret = UnloadModel(ge_root_model, graph_id);
if (middle_ret != SUCCESS) {
REPORT_INNER_ERROR("E19999", "UnloadModel for graph:%u failed, check invalid", graph_id);
GELOGE(middle_ret, "[Unload][Model] model failed, graph_id=%u.", graph_id);
ret = middle_ret;
}
rt_ret = rtDeviceReset(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
REPORT_CALL_ERROR("E19999", "Call rtDeviceReset failed, device_id:%u, graph_id:%u",
GetContext().DeviceId(), graph_id);
GELOGE(RT_FAILED, "[Call][RtDeviceReset] failed, device_id:%u, graph_id:%u", GetContext().DeviceId(), graph_id);
ret = FAILED;
}
}

RemoveCompilerStages(graph_id);
@@ -2120,8 +1984,6 @@ Status GraphManager::SummaryHandle(const GraphId &graph_id, std::vector<GeTensor
Status GraphManager::CheckpointHandle(const GraphId &graph_id, const ComputeGraphPtr &compute_graph,
const std::vector<GeTensor> &outputs) {
GELOGI("[GraphManager] CheckpointHandle, outputsSize=%zu.", outputs.size());
std::vector<InputOutputDescInfo> outputs_desc = graph_executor_.GetOutputsDesc();
GELOGI("[GraphManager] CheckpointHandle, outputsDescSize=%zu.", outputs_desc.size());

std::map<string, Tensor> save_results;
NodePtr netoutput = nullptr;
@@ -2786,160 +2648,6 @@ void GraphManager::ChangeConstTypeWhenTraining(const ComputeGraphPtr &compute_gr
}
}

Status GraphManager::LoadGraphAsync(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node) {
GELOGI("[LoadGraphAsync] run_graph_flag[%d], graph_id[%u]", options_.run_graph_flag, graph_node->GetGraphId());
if (options_.run_graph_flag && ge_root_model != nullptr) {
ge_root_model->SetTrainFlag(GetTrainFlag());
// synchronization run graph with model
ModelIdInfo model_id_info;
bool is_unknown_shape = false;
GE_CHK_STATUS_RET(ge_root_model->CheckIsUnknownShape(is_unknown_shape));
if (!is_unknown_shape) {
if (getenv(kEnvGeuseStaticMemory) != nullptr) {
GELOGI("[LoadGraphAsync] GE_USE_STATIC_MEMORY is seted.");
} else {
auto root_graph = ge_root_model->GetRootGraph();
GE_CHECK_NOTNULL(root_graph);
auto name_to_model = ge_root_model->GetSubgraphInstanceNameToModel();
GeModelPtr ge_model = name_to_model[root_graph->GetName()];
GE_CHK_STATUS_RET(CheckAndReleaseMemory(ge_model, graph_node));
}
}
GE_TIMESTAMP_START(LoadGraph);
auto listener = MakeShared<RunAsyncListener>();
GE_CHECK_NOTNULL(listener);
Status ret = GraphLoader::LoadModelOnline(model_id_info.model_id, ge_root_model, listener);
GE_TIMESTAMP_EVENT_END(LoadGraph, "GraphManager::LoadGraphAsync");
if (ret != SUCCESS) {
GELOGE(ret, "[Load][ModelOnline] Failed, model_id:%u", model_id_info.model_id);
graph_node->SetRunFlag(false);
return ret;
}
graph_node->SetLoadFlag(true);
ge_root_model->SetModelId(model_id_info.model_id);
graph_node->SetGeRootModel(ge_root_model);
}
return SUCCESS;
}

void GraphManager::ReleaseMemory(const GeModelPtr &ge_model, GraphNodePtr &graph_node,
const std::vector<uint32_t> &model_ids, uint32_t graph_id, uint64_t session_id) {
rtError_t rt_ret = rtSetDevice(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
REPORT_CALL_ERROR("E19999", "Call rtSetDevice failed, device_id:%u", GetContext().DeviceId());
GELOGE(RT_FAILED, "[Call][RtSetDevice] failed, device_id=%u.", GetContext().DeviceId());
return;
}
for (auto model_id : model_ids) {
uint64_t max_memory_size = 0;
Status result = GraphLoader::GetMaxUsedMemory(model_id, max_memory_size);
if (result != SUCCESS) {
continue;
}
GELOGI("CheckAndReleaseMemory try to UnloadGraph[%u], model[%u] which MaxUsedMemory[%lu].", graph_id, model_id,
max_memory_size);
if (model_ids.size() > 1) {
result = ge_model->GetSessionId(model_id, session_id);
if (result != SUCCESS) {
GELOGW("[GraphManager:] get session failed when dynamic memory, modelId=%u, graphId=%u.", model_id,
graph_id);
continue;
}
}
result = GraphLoader::DestroyAicpuKernel(session_id, model_id, 0);
if (result != SUCCESS) {
GELOGW("[GraphManager:] destroy aicpu kernel failed when dynamic memory, modelId=%u, graphId=%u.", model_id,
graph_id);
}
result = GraphLoader::UnloadModel(model_id);
if (result != SUCCESS) {
GELOGW("[GraphManager:] unload model failed, modelId=%u, graphId=%u.", model_id, graph_id);
}
GELOGI("CheckAndReleaseMemory UnloadGraph[%u], model[%u] success.", graph_id, model_id);
}
graph_node->SetLoadFlag(false);
// Allow model to be loaded agagin without adding graph again
graph_node->SetLoadCount(graph_node->GetLoadRecord());
graph_node->SetLoadRecord(kNeverLoaded);
GeRootModelPtr ge_root_model = graph_node->GetGeRootModel();
if (ge_root_model == nullptr) {
GELOGW("ge_root_model is null, graph_id:%u", graph_id);
return;
}
ge_root_model->ClearAllModelId();
rt_ret = rtDeviceReset(GetContext().DeviceId());
if (rt_ret != RT_ERROR_NONE) {
REPORT_CALL_ERROR("E19999", "Call rtDeviceReset failed, device_id:%u", GetContext().DeviceId());
GELOGE(RT_FAILED, "[Call][RtDeviceReset] failed, device_id:%u.", GetContext().DeviceId());
return;
}
}

Status GraphManager::CheckAndReleaseMemory(const GeModelPtr &ge_model, const GraphNodePtr &graph_node) {
GELOGI("CheckAndReleaseMemory graph_id[%u]", graph_node->GetGraphId());
int64_t value = 0;
bool ret = ge::AttrUtils::GetInt(ge_model, ATTR_MODEL_MEMORY_SIZE, value);
int64_t memory_size = ret ? value : 0;
ret = ge::AttrUtils::GetInt(ge_model, ATTR_MODEL_WEIGHT_SIZE, value);
int64_t weight_size = ret ? value : 0;
ret = ge::AttrUtils::GetInt(ge_model, MODEL_ATTR_SESSION_ID, value);
uint64_t session_id = ret ? value : 0;

int64_t free_memory = 0;
Status result = GraphLoader::GetMemoryInfo(free_memory);
if (result != SUCCESS) {
return result;
}

GELOGI(
"CheckAndReleaseMemory Graph[%u] need memory_size[%ld], weight_size[%ld],"
" Device[%u] free_memory_size[%ld]",
graph_node->GetGraphId(), memory_size, weight_size, GetContext().DeviceId(), free_memory);
if (ge::CheckInt64AddOverflow(memory_size, weight_size) != SUCCESS) {
REPORT_INNER_ERROR("E19999", "memory_size:%ld and weight_size:%ld will overflow after add, check invalid",
memory_size, weight_size);
GELOGE(INTERNAL_ERROR, "[Check][Param] memory_size:%ld and weight_size:%ld will overflow after add",
memory_size, weight_size);
return INTERNAL_ERROR;
}
if (free_memory >= (memory_size + weight_size)) {
return SUCCESS;
}

std::lock_guard<std::mutex> lock(unload_model_mutex_);

std::map<GraphId, GraphNodePtr> graph_map;
{
std::lock_guard<std::mutex> lock(member_mutex_);
graph_map = graph_map_;
}

for (auto &it : graph_map) {
auto graph_id = it.second->GetGraphId();
auto model = it.second->GetGeRootModel();
if (model == nullptr) {
continue;
}
auto model_id = model->GetModelId();
auto model_ids = model->GetAllModelId();
// unload model not release
bool is_unknown_shape = false;
GE_CHK_STATUS_RET(model->CheckIsUnknownShape(is_unknown_shape));
if (is_unknown_shape) {
GELOGD("model_id[%u] graph_id[%u] is unknown model, not release memory", model_id, graph_id);
continue;
}
// not loaded,no need unload
if (!it.second->GetLoadFlag()) {
GELOGI("CheckAndReleaseMemory graph[%u] has not been loaded.", graph_id);
continue;
}
ReleaseMemory(ge_model, it.second, model_ids, graph_id, session_id);
}

return SUCCESS;
}

Status GraphManager::ProcessSubGraphWithMultiThreads(GraphManager *graph_manager, GraphId root_graph_id,
const SubGraphInfoPtr &sub_graph_info_ptr,
const std::string &root_graph_name,
@@ -3069,14 +2777,14 @@ Status GraphManager::IncreBuild(const GraphNodePtr &graph_node, GeModelPtr &ge_m
return FAILED;
}

Status GraphManager::CheckIncreBuildAndPreRun(GraphManager *graph_manager, const PreRunArgs &args,
Status GraphManager::CheckIncreBuildAndPreRun(const PreRunArgs &args,
GraphNodePtr &graph_node, GeRootModelPtr &ge_root_model) {
if (!graph_manager->IsGraphNeedBuild(graph_node)) {
if (!IsGraphNeedBuild(graph_node)) {
ge_root_model = graph_node->GetGeRootModel();
return SUCCESS;
}
if (graph_node->GetBuildFlag()) {
ReturnError(graph_manager, args.callback, PARAM_INVALID,
ReturnError(args.callback, PARAM_INVALID,
"The graph " + std::to_string(graph_node->GetGraphId()) +
" need to re-build, you should remove it"
" from GE first, then AddGraph again and rebuild it.");
@@ -3084,55 +2792,53 @@ Status GraphManager::CheckIncreBuildAndPreRun(GraphManager *graph_manager, const
}
// check need incre build.
GeModelPtr ge_model = nullptr;
if (graph_manager->IncreBuild(graph_node, ge_model) != SUCCESS) {
if (IncreBuild(graph_node, ge_model) != SUCCESS) {
std::vector<GeTensor> ge_inputs;
for (const auto &item: args.input_tensor) {
ge_inputs.emplace_back(TensorAdapter::AsGeTensor(item));
}
Status ret = graph_manager->PreRun(graph_node, ge_inputs, ge_root_model, args.session_id);
Status ret = PreRun(graph_node, ge_inputs, ge_root_model, args.session_id);
// release rts generate context
RtContextUtil::GetInstance().DestroyRtContexts(args.session_id, graph_node->GetGraphId());
if (ret != SUCCESS) {
ReturnError(graph_manager, args.callback, ret, "PreRun Failed.");
ReturnError(args.callback, ret, "PreRun Failed.");
return ret;
}
}
graph_node->SetBuildFlag(true);
graph_manager->var_acc_ctrl_.SetGraphBuildEnd(graph_node->GetGraphId());
var_acc_ctrl_.SetGraphBuildEnd(graph_node->GetGraphId());
return SUCCESS;
}

void GraphManager::PreRunThread(GraphManager *graph_manager) {
void GraphManager::PreRunThread() {
if (prctl(PR_SET_NAME, ("GE_PreRun")) != 0) {
GELOGW("Set thread name failed.");
}

PreRunArgs args;
while (graph_manager->thread_run_flag_) {
bool pop_status = graph_manager->prerun_args_q_.Pop(args);
if (!pop_status) {
while (thread_run_flag_) {
if (!prerun_args_q_.Pop(args)) {
continue;
}

GELOGI("[PreRunThread] A new loop start, graph_id:%u.", args.graph_id);

ErrorManager::GetInstance().SetErrorContext(args.error_context);
ErrorManager::GetInstance().SetStage(error_message::kModelCompile, error_message::kOther);
GetContext().SetSessionId(args.session_id);
GetThreadLocalContext() = args.context;
graph_manager->UpdateLocalOmgContext(args.graph_id);
UpdateLocalOmgContext(args.graph_id);

// find graph
GraphNodePtr graph_node = nullptr;
Status ret = graph_manager->GetGraphNode(args.graph_id, graph_node);
Status ret = GetGraphNode(args.graph_id, graph_node);
if (ret != SUCCESS) {
ReturnError(graph_manager, args.callback, GE_GRAPH_GRAPH_NODE_NULL,
ReturnError(args.callback, GE_GRAPH_GRAPH_NODE_NULL,
"[RunGraph] graph not exist, graph_id=" + std::to_string(args.graph_id));
return;
}
// more than one graph owns same graph_id
uint32_t count = 0;
if (graph_manager->GetGraphCount(args.graph_id, count) != SUCCESS) {
if (GetGraphCount(args.graph_id, count) != SUCCESS) {
GELOGE(INTERNAL_ERROR, "[Get][GraphCount] failed, graph id:%u.", args.graph_id);
return;
}
@@ -3142,7 +2848,7 @@ void GraphManager::PreRunThread(GraphManager *graph_manager) {
// In online inference concurrency senario, graph_node is allowed to be locked for 'count' times
graph_node->SetSemSize(count);
graph_node->Lock();
graph_manager->run_args_q_.Push(RunArgs( { graph_node, args.graph_id, args.session_id, args.error_context,
PushGraph(RunArgs( { graph_node, args.graph_id, args.session_id, args.error_context,
args.input_tensor, graph_node->GetGeRootModel(), GetThreadLocalContext(), args.callback }));
GELOGI("[PreRunThread] Loop end. Start to run with cached build model.");
continue;
@@ -3151,7 +2857,7 @@ void GraphManager::PreRunThread(GraphManager *graph_manager) {
graph_node->Lock();

if (graph_node->GetRunFlag()) {
ReturnError(graph_manager, args.callback, GE_GRAPH_ALREADY_RUNNING,
ReturnError(args.callback, GE_GRAPH_ALREADY_RUNNING,
"[RunGraph] graph already running, graph id=" + std::to_string(args.graph_id));
graph_node->Unlock();
return;
@@ -3162,25 +2868,25 @@ void GraphManager::PreRunThread(GraphManager *graph_manager) {

ComputeGraphPtr compute_graph_tmp = GraphUtils::GetComputeGraph(*(graph_node->GetGraph()));
if (compute_graph_tmp == nullptr) {
ReturnError(graph_manager, args.callback, GE_GRAPH_GRAPH_NODE_NULL,
ReturnError(args.callback, GE_GRAPH_GRAPH_NODE_NULL,
"[RunGraph] compute_graph_tmp is NULL, graph id = %u.");
graph_node->Unlock();
return;
}
// when set incre build, save cache helper.
graph_manager->AddModelCacheHelperToMap(args.graph_id, args.session_id, compute_graph_tmp);
AddModelCacheHelperToMap(args.graph_id, args.session_id, compute_graph_tmp);

std::vector<GeModelPtr> ge_models;

if (graph_manager->options_.local_fmk_op_flag) {
graph_manager->GetCompilerStages(graph_node->GetGraphId()).optimizer.TranFrameOp(compute_graph_tmp);
if (options_.local_fmk_op_flag) {
GetCompilerStages(graph_node->GetGraphId()).optimizer.TranFrameOp(compute_graph_tmp);
}

// it will not execute graph preprocess, optimize, parition, build if the graph has built successful.
GELOGI("Start for run graph async.");
GeRootModelPtr ge_root_model = nullptr;

ret = CheckIncreBuildAndPreRun(graph_manager, args, graph_node, ge_root_model);
ret = CheckIncreBuildAndPreRun(args, graph_node, ge_root_model);
if (ret != SUCCESS) {
graph_node->SetRunFlag(false);
if (!ge::Analyzer::GetInstance()->IsEnableNetAnalyzeDebug()) {
@@ -3193,252 +2899,49 @@ void GraphManager::PreRunThread(GraphManager *graph_manager) {
continue;
}
}
graph_manager->run_args_q_.Push(RunArgs( { graph_node, args.graph_id, args.session_id, args.error_context,

PushGraph(RunArgs( { graph_node, args.graph_id, args.session_id, args.error_context,
args.input_tensor, ge_root_model, GetThreadLocalContext(), args.callback }));
GELOGI("[PreRunThread] Loop end.");
}
}

void GraphManager::ParseInputsDimsForData(const std::vector<ge::Tensor> &input_tensor) {
GELOGD("Start parse input dims from data.");
for (size_t i = 0; i < input_tensor.size(); ++i) {
const TensorDesc &tensor_desc = input_tensor[i].GetTensorDesc();
const Shape &shape = tensor_desc.GetShape();
const auto &shape_dims = shape.GetDims();
GELOGD("Input tensor dims is %s.", formats::JoinToString(shape_dims).c_str());
GetLocalOmgContext().user_real_input_dims.emplace_back(shape_dims);
}
}

Status GraphManager::ParseInputsDimsForGetNexNosinkAndData(const vector<NodePtr> &dynamic_nodes,
const std::vector<ge::Tensor> &input_tensor) {
GELOGD("Start parse inputs dims when coexist data and getnext sink.");
for (size_t i = 0; i < dynamic_nodes.size(); ++i) {
auto op_desc = dynamic_nodes.at(i)->GetOpDesc();
if (op_desc == nullptr) {
continue;
}
GeAttrValue::INT index = 0;
if (!(AttrUtils::GetInt(op_desc, ATTR_NAME_INDEX, index))) {
REPORT_CALL_ERROR("E19999", "Get Attr:%s from op:%s(%s) fail", ATTR_NAME_INDEX.c_str(),
op_desc->GetName().c_str(), op_desc->GetType().c_str());
GELOGE(PARAM_INVALID, "[Get][Attr] %s from op:%s(%s) fail", ATTR_NAME_INDEX.c_str(),
op_desc->GetName().c_str(), op_desc->GetType().c_str());
return PARAM_INVALID;
}
if (static_cast<size_t>(index) > input_tensor.size()) {
REPORT_INNER_ERROR("E19999", "Attr:%s in op:%s(%s) value:%ld > param input_tensor.size:%zu, "
"check invalid", ATTR_NAME_INDEX.c_str(),
op_desc->GetName().c_str(), op_desc->GetType().c_str(),
index, input_tensor.size());
GELOGE(PARAM_INVALID, "[Check][Param] Attr:%s in op:%s(%s) value:%ld > param input_tensor.size:%zu",
ATTR_NAME_INDEX.c_str(), op_desc->GetName().c_str(), op_desc->GetType().c_str(),
index, input_tensor.size());
return PARAM_INVALID;
}

const TensorDesc &tensor_desc = input_tensor[i].GetTensorDesc();
const Shape &shape = tensor_desc.GetShape();
const auto &shape_dims = shape.GetDims();
GELOGI("Shape dims of %zu data is %s.", index, formats::JoinToString(shape_dims).c_str());
GetLocalOmgContext().user_real_input_dims.emplace_back(std::move(shape_dims));
void GraphManager::PushGraph(const RunArgs &args) {
if (executor_ == nullptr) {
GELOGW("Just compile model, not support execute.");
return;
}
return SUCCESS;
}

Status GraphManager::ParseInputsDims(const std::vector<ge::Tensor> &input_tensor) {
GELOGI("Start parse input dims of %zu input tensor.", input_tensor.size());
GetLocalOmgContext().user_real_input_dims.clear();
if (!GetLocalOmgContext().dynamic_node_type.empty()) {
vector<NodePtr> data_nodes;
vector<NodePtr> getnext_nosink_nodes;
data_nodes = GetLocalOmgContext().data_nodes;
getnext_nosink_nodes = GetLocalOmgContext().getnext_nosink_nodes;
GELOGD("Data nodes count is %zu, getnext nosink nodes count is %zu.", data_nodes.size(),
getnext_nosink_nodes.size());
if (GetLocalOmgContext().dynamic_node_type == DATA) {
if (getnext_nosink_nodes.empty()) {
// just data or data+getnext_sink
ParseInputsDimsForData(input_tensor);
} else {
// data+getnext_nosink, but only need to get shape_dims of data
if (ParseInputsDimsForGetNexNosinkAndData(data_nodes, input_tensor) != SUCCESS) {
GELOGE(PARAM_INVALID, "[Parse][Dims] from data failed, when data coexist with getnext nosink.");
return PARAM_INVALID;
}
}
} else {
if (getnext_nosink_nodes.empty()) {
// just getnext_sink or getnext_sink+data, need to get shape_dims from aicpu op
GELOGI("Need to get dims from aicpu op: GETDYNAMICDIMS.");
return SUCCESS;
} else {
if (data_nodes.empty()) {
// just getnext_nosink
ParseInputsDimsForData(input_tensor);
} else {
// getnext_nosink + data, but only need to get shape_dims of getnext_nosink
if (ParseInputsDimsForGetNexNosinkAndData(getnext_nosink_nodes, input_tensor) != SUCCESS) {
GELOGE(PARAM_INVALID, "[Parse][Dims] from getnext nosink failed, when data coexist with getnext nosink");
return PARAM_INVALID;
}
}
}
}
}
GELOGI("Parse %zu inputs dims success.", GetLocalOmgContext().user_real_input_dims.size());
return SUCCESS;
(void)executor_->PushGraph(args);
}

void GraphManager::RunThread(GraphManager *graph_manager) {
ErrorManager::GetInstance().SetStage(error_message::kModelExecute, error_message::kModelExecute);
if (prctl(PR_SET_NAME, ("GE_Run")) != 0) {
GELOGW("Set thread name failed.");
}

RunArgs args;
while (graph_manager->thread_run_flag_) {
bool pop_status = graph_manager->run_args_q_.Pop(args);
if (!pop_status) {
continue;
}

GELOGI("[RunThread] A new loop start, graph_id:%u.", args.graph_id);

ErrorManager::GetInstance().SetErrorContext(args.error_context);
GetContext().SetSessionId(args.session_id);
GetThreadLocalContext() = args.context;
graph_manager->UpdateLocalOmgContext(args.graph_id);

Status ret;
// parse inputs.dims to vector<vector<uint64_t>> dynamic_dims
ret = graph_manager->ParseInputsDims(args.input_tensor);
if (ret != SUCCESS) {
ReturnError(graph_manager, args.callback, ret, "ParseInputsDims failed, thread exit.");
args.graph_node->Unlock();
return;
}

args.graph_node->UpdateLoadFlag();
if (!args.graph_node->GetLoadFlag()) {
ErrorManager::GetInstance().SetStage(error_message::kModelLoad, error_message::kModelLoad);
args.ge_root_model->SetTrainFlag(graph_manager->GetTrainFlag());
ret = graph_manager->LoadGraphAsync(args.ge_root_model, args.graph_node);
if (ret != SUCCESS || args.ge_root_model == nullptr) {
StopQueue(graph_manager);
ReturnError(graph_manager, args.callback, ret, "LoadGraphAsync failed, thread exit.");
args.graph_node->Unlock();
return;
}
// control the times of graph loading in multi-thread scenario
args.graph_node->DecreaseLoadCount();
args.graph_node->IncreaseLoadRecord();
void GraphManager::SetRunContext(const GraphNodePtr &graph_node) {
OmeContext ome_context;
ome_context.need_multi_batch = GetLocalOmgContext().need_multi_batch;
ome_context.dynamic_node_type = GetLocalOmgContext().dynamic_node_type;
ome_context.dynamic_shape_dims = StringUtils::Split(GetLocalOmgContext().dynamic_dims, ';');
ome_context.user_input_dims = GetLocalOmgContext().user_input_dims;

args.graph_node->SetLoadFlag(true);
GELOGI("LoadGraph[%u], model[%u] success and set LoadFlag to true.", args.graph_node->GetGraphId(),
args.ge_root_model->GetModelId());
}
ome_context.data_nodes = GetLocalOmgContext().data_nodes;
ome_context.getnext_nosink_nodes = GetLocalOmgContext().getnext_nosink_nodes;

ErrorManager::GetInstance().SetStage(error_message::kModelExecute, error_message::kModelExecute);
if (graph_manager->GetTrainFlag()) {
ret = graph_manager->graph_executor_.SetGraphContext(graph_manager->GetGraphContext());
if (ret != SUCCESS) {
GELOGW("[GraphManager] SetGraphContext failed, graph_id=%u.", args.graph_id);
}
graph_manager->graph_executor_.SetTrainFlag(graph_manager->options_.train_graph_flag);
}
ome_context.user_real_input_dims = GetLocalOmgContext().user_real_input_dims;

ret = graph_manager->graph_executor_.ExecuteGraphAsync(args.graph_id, args.graph_node->GetGeRootModel(),
args.input_tensor, args.callback);
args.graph_node->SetRunFlag(false);
if (ret != SUCCESS) {
ReturnError(graph_manager, args.callback, ret, "ExecuteGraphAsync failed, thread exit.");
args.graph_node->Unlock();
return;
}
args.graph_node->Unlock();
GELOGI("[GraphManager] Run graph async success, graph_id=%u.", args.graph_id);
}
graph_node->SetOmeContext(ome_context);
}

void GraphManager::StopQueue(GraphManager *graph_manager) {
if (graph_manager == nullptr) {
return;
}

graph_manager->thread_run_flag_.store(false);
graph_manager->prerun_args_q_.Stop();
graph_manager->run_args_q_.Stop();
void GraphManager::StopQueue() {
thread_run_flag_.store(false);
prerun_args_q_.Stop();
}

void GraphManager::ReturnError(GraphManager *graph_manager, RunAsyncCallback callback, Status ret, const string &log) {
if (graph_manager == nullptr) {
return;
}
StopQueue(graph_manager);
void GraphManager::ReturnError(RunAsyncCallback callback, Status ret, const string &log) {
StopQueue();
GELOGE(ret, "%s.", log.c_str());
std::vector<ge::Tensor> outputs;
callback(ret, outputs);
}

void GraphManager::ReturnError(GraphManager *graph_manager, GraphNodePtr &graph_node, RunAsyncCallback callback,
Status ret, const string &log) {
std::vector<ge::Tensor> outputs;
auto compute_graph = GraphUtils::GetComputeGraph(*graph_node->GetGraph());
if (graph_manager == nullptr || compute_graph == nullptr) {
REPORT_INNER_ERROR("E19999", "Param graph_manager or compute_graph in graph_node is nullptr, check invalid");
GELOGE(GRAPH_FAILED, "[Check][Param] compute graph or graph manager is nullptr");
callback(GRAPH_FAILED, outputs);
return;
}

for (const auto &node : compute_graph->GetAllNodes()) {
if (node->GetType() != "NetOutput") {
continue;
}
for (size_t i = 0; i < node->GetAllInDataAnchorsSize(); i++) {
auto input_desc = node->GetOpDesc()->MutableInputDesc(i);
GeShape ge_shape(input_desc->GetShape().GetDims());
GeTensorDesc ge_tensor_desc;
ge_tensor_desc.SetShape(ge_shape);
GeTensor ge_tensor(ge_tensor_desc);
int64_t len = 1;
if (input_desc->GetShape().GetDims() != std::vector<int64_t>({})) {
len = input_desc->GetShape().GetShapeSize();
}
if (len < 0) {
REPORT_INNER_ERROR("E19999", "InputIndex:%zu ShapeSize:%ld of op:%s(%s) < 0, unknown shape is not support, "
"check invalid", i, len,
node->GetName().c_str(), node->GetType().c_str());
GELOGE(GRAPH_FAILED, "[Check][Param] InputIndex:%zu ShapeSize:%ld of op:%s(%s) < 0, "
"unknown shape is not support", i, len, node->GetName().c_str(), node->GetType().c_str());
callback(GRAPH_FAILED, outputs);
return;
} else if (len == 0) {
GELOGI("getted shape size is 0.Do process as empty tensor!");
len = 1;
}
auto length = GetSizeInBytes(len, input_desc->GetDataType());
auto aligned_ptr = MakeShared<AlignedPtr>(length, kAlignment);
if (aligned_ptr == nullptr) {
REPORT_CALL_ERROR("E19999", "New AlignedPtr failed, len:%ld", length);
GELOGE(GRAPH_FAILED, "[Create][AlignedPtr] failed, len:%ld", length);
return;
}
ge_tensor.SetData(aligned_ptr, length);
ge::Tensor tensor = TensorAdapter::AsTensor(ge_tensor);
// To avoid global step too small and can not stop, totally set a bigger value
auto ptr = aligned_ptr->MutableGet();
for (int64_t i = 0; i < length; i++) {
ptr[i] = 0x7F; // here stands for a positive max value
}
outputs.emplace_back(std::move(tensor));
}
}
callback(SUCCESS, outputs);
return;
}

bool GraphManager::IsGraphNeedRebuild(uint32_t graph_id) {
// find graph
GraphNodePtr graph_node = nullptr;
@@ -3649,6 +3152,7 @@ Status GraphManager::Build(const GraphNodePtr &graph_node, ComputeGraphPtr &comp
GraphUtils::DumpGEGraph(compute_graph, "Build", is_always_dump);
GraphUtils::DumpGEGraphToOnnx(*compute_graph, "Build");

SetRunContext(graph_node);
graph_node->SetGeRootModel(ge_root_model);
return SUCCESS;
}


+ 15
- 48
ge/graph/manager/graph_manager.h View File

@@ -31,7 +31,6 @@
#include "external/graph/types.h"
#include "external/ge/ge_api_types.h"
#include "graph/build/graph_builder.h"
#include "graph/execute/graph_execute.h"
#include "graph/ge_local_context.h"
#include "graph/load/graph_loader.h"
#include "graph/manager/graph_manager_utils.h"
@@ -41,11 +40,12 @@
#include "graph/preprocess/graph_preprocess.h"
#include "graph/tuning_utils.h"
#include "model/ge_model.h"
#include "common/executor.h"

namespace ge {
class GraphManager {
public:
GraphManager();
GraphManager() = default;
~GraphManager() = default;

///
@@ -54,7 +54,7 @@ class GraphManager {
/// @param [in] options user config params
/// @return Status result of function
///
Status Initialize(const std::map<string, string> &options);
Status Initialize(const std::map<string, string> &options, Executor *executor = nullptr);

///
/// @ingroup ge_graph
@@ -113,7 +113,7 @@ class GraphManager {
/// @param [out] outputs output data
/// @return Status result of function
///
Status RunGraphWithStreamAsync(const GraphId &graph_id, rtStream_t stream, uint64_t session_id,
Status RunGraphWithStreamAsync(const GraphId &graph_id, rtStream_t stream, uint64_t session_id,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs);

///
@@ -227,34 +227,18 @@ class GraphManager {
RunAsyncCallback callback;
};

struct RunArgs {
GraphNodePtr graph_node;
GraphId graph_id;
uint64_t session_id;
struct error_message::Context error_context;
std::vector<ge::Tensor> input_tensor;
GeRootModelPtr ge_root_model;
GEThreadLocalContext context;
RunAsyncCallback callback;
};

void AddGraphNode(GraphId graph_id, const GraphNodePtr &graph_node);
void RemoveGraphNode(GraphId graph_id);
bool HasGraphNode(GraphId graph_id);
Status GetGraphNode(const GraphId &graph_id, GraphNodePtr &out);

std::shared_ptr<GraphModelListener> GetModelListener() const { return graph_run_listener_; }

static Status ProcessSubGraphWithMultiThreads(GraphManager *graph_manager, GraphId root_graph_id,
const SubGraphInfoPtr &sub_graph_info_ptr,
const std::string &root_graph_name,
uint64_t session_id,
const struct error_message::Context &error_context,
const GEThreadLocalContext &ge_context);
Status ParseInputsDims(const std::vector<ge::Tensor> &input_tensor);
void ParseInputsDimsForData(const std::vector<ge::Tensor> &input_tensor);
Status ParseInputsDimsForGetNexNosinkAndData(const vector<NodePtr> &dynamic_nodes,
const std::vector<ge::Tensor> &input_tensor);

Status RunCustomPass(const GraphNodePtr &graph_node);
Status PreRun(const GraphNodePtr &graph_node, const std::vector<GeTensor> &inputs, GeRootModelPtr &ge_root_model,
uint64_t session_id = INVALID_SESSION_ID);
@@ -350,10 +334,6 @@ class GraphManager {

Status SubexpressionMigration(ComputeGraphPtr &compute_graph);

Status LoadGraphAsync(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node);

Status CheckAndReleaseMemory(const GeModelPtr &ge_model, const GraphNodePtr &graph_node);

bool CheckModelLoad(const GeRootModelPtr &ge_model, bool load_flag);

Status LoadGraph(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node);
@@ -368,12 +348,12 @@ class GraphManager {
void RemoveModelCacheHelper(const GraphId &graph_id);
ModelCacheHelperPtr FindModelCacheHelper(GraphId graph_id);

static void PreRunThread(GraphManager *graph_manager);
static void RunThread(GraphManager *graph_manager);
static void StopQueue(GraphManager *graph_manager);
static void ReturnError(GraphManager *graph_manager, RunAsyncCallback callback, Status ret, const string &log);
static void ReturnError(GraphManager *graph_manager, GraphNodePtr &graph_node, RunAsyncCallback callback,
Status ret, const string &log);
void SetRunContext(const GraphNodePtr &graph_node);
void PushGraph(const RunArgs &args);
void PreRunThread();
void StopQueue();
void ReturnError(RunAsyncCallback callback, Status ret, const string &log);

void ChangeConstTypeWhenTraining(const ComputeGraphPtr &compute_graph);

@@ -409,11 +389,7 @@ class GraphManager {
CompilerStages &GetCompilerStages(GraphId graph_id);
void RemoveCompilerStages(GraphId graph_id);

static Status CheckIncreBuildAndPreRun(GraphManager *graph_manager, const PreRunArgs &args, GraphNodePtr &graph_node,
GeRootModelPtr &ge_root_model);

void ReleaseMemory(const GeModelPtr &ge_model, GraphNodePtr &graph_node, const std::vector<uint32_t> &model_ids,
uint32_t graph_id, uint64_t session_id);
Status CheckIncreBuildAndPreRun(const PreRunArgs &args, GraphNodePtr &graph_node, GeRootModelPtr &ge_root_model);

Status CheckRepeatAdd(uint32_t graph_id, bool &is_added);

@@ -431,34 +407,25 @@ class GraphManager {

static Status CheckGraphAdded(const GraphId &graph_id, const Graph &graph);

std::atomic_bool thread_run_flag_;
std::atomic_bool thread_run_flag_{false};
BlockingQueue<PreRunArgs> prerun_args_q_{};
BlockingQueue<RunArgs> run_args_q_{};
std::thread prerun_thread_;
std::thread run_thread_;
ComputeGraphPtr compute_graph_;
std::map<GraphId, GraphNodePtr> graph_map_;
std::map<GraphId, ModelCacheHelperPtr> cache_helper_map_;

// for run graph synchronous return
std::mutex sync_run_mutex_;
std::condition_variable condition_;
// run graph synchronization call back listener
std::shared_ptr<GraphModelListener> graph_run_listener_;

// summary and checkpoint callback function list for ME, key is summary or checkpoint
std::map<std::string, std::function<Status(uint32_t, const std::map<std::string, ge::Tensor> &)>> me_callback_map_;

std::map<std::string, std::function<Status(uint32_t, const std::map<AscendString, ge::Tensor> &)>> callback_map_;

bool init_flag_;

bool init_flag_{false};
GraphManagerOptions options_;
GraphContextPtr graph_context_ = nullptr;
map<GraphId, OmgContext> omg_contexts_;

map<GraphId, CompilerStages> compiler_stages_;
GraphExecutor graph_executor_;
Executor *executor_{nullptr};

VarAccelerateCtrl var_acc_ctrl_;



+ 6
- 0
ge/graph/manager/graph_manager_utils.h View File

@@ -33,6 +33,7 @@
#include "framework/common/debug/ge_log.h"
#include "framework/common/ge_inner_error_codes.h"
#include "graph/compute_graph.h"
#include "graph/common/local_context.h"
#include "external/graph/graph.h"
#include "graph/model.h"
#include "model/ge_model.h"
@@ -154,6 +155,9 @@ class GraphNode {
bool GetRunFlag() const { return run_flag_; }
void SetRunFlag(bool flag) { run_flag_ = flag; }

void SetOmeContext(const OmeContext &context) { context_ = context; }
OmeContext &GetOmeContext() { return context_; }

bool IsAsync() const { return async_; }
void SetAsync(bool flag) { async_ = flag; }

@@ -196,6 +200,8 @@ class GraphNode {
bool run_flag_;
std::vector<SubGraphInfoPtr> subgraph_ptr_list_;

OmeContext context_;

GraphPtr graph_;
ComputeGraphPtr compute_graph_;
bool build_flag_;


+ 41
- 3
ge/session/inner_session.cc View File

@@ -124,7 +124,7 @@ Status InnerSession::Initialize() {
GE_CHK_STATUS_RET(dump_properties.InitByOptions(), "Init dump properties failed.");
GE_CHK_STATUS_RET(AddDumpProperties(dump_properties), "[Add][DumpProperties] failed.");

ret = graph_manager_.Initialize(options_);
ret = InnerInitialize();
if (ret != SUCCESS) {
GELOGE(ret, "[Init][GraphManager] failed, InnerSession:%lu.", session_id_);
REPORT_CALL_ERROR("E19999", "GraphManager initialize failed, InnerSession:%lu.", session_id_);
@@ -136,7 +136,7 @@ Status InnerSession::Initialize() {
if (ret != SUCCESS) {
GELOGE(ret, "[Set][MemoryMallocSize] failed.");
REPORT_CALL_ERROR("E19999", "VarManager SetMemoryMallocSize failed, InnerSession:%lu.", session_id_);
(void)graph_manager_.Finalize();
(void)InnerFinalize();
GE_CHK_STATUS(RemoveDumpProperties(), "[Remove][DumpProperties] failed.");
GE_CHK_RT(rtDeviceReset(static_cast<int32_t>(GetContext().DeviceId())));
return ret;
@@ -162,7 +162,7 @@ Status InnerSession::Finalize() {
return SUCCESS;
}
UpdateThreadContext(std::map<std::string, std::string>{});
Status ret = graph_manager_.Finalize();
Status ret = InnerFinalize();
if (ret != SUCCESS) {
// Subsequent code execution is required, so no return is required
GELOGE(ret, "[Finalize][GraphManager] failed, InnerSession:%lu.", session_id_);
@@ -188,6 +188,44 @@ Status InnerSession::Finalize() {
return ret;
}

Status InnerSession::InnerInitialize() {
Status ret = model_executor_.Initialize(options_);
if (ret != SUCCESS) {
GELOGE(ret, "[Init][GraphExecutor] failed, InnerSession:%lu.", session_id_);
REPORT_CALL_ERROR("E19999", "GraphExecutor initialize failed, InnerSession:%lu.", session_id_);
GE_CHK_STATUS(RemoveDumpProperties(), "[Remove][DumpProperties] failed.");
return ret;
}

ret = graph_manager_.Initialize(options_, &model_executor_);
if (ret != SUCCESS) {
GELOGE(ret, "[Init][GraphManager] failed, InnerSession:%lu.", session_id_);
REPORT_CALL_ERROR("E19999", "GraphManager initialize failed, InnerSession:%lu.", session_id_);
GE_CHK_STATUS(RemoveDumpProperties(), "[Remove][DumpProperties] failed.");
return ret;
}

return SUCCESS;
}

Status InnerSession::InnerFinalize() {
Status ret = graph_manager_.Finalize();
if (ret != SUCCESS) {
// Subsequent code execution is required, so no return is required
GELOGE(ret, "[Finalize][GraphManager] failed, InnerSession:%lu.", session_id_);
REPORT_CALL_ERROR("E19999", "GraphManager Finalize failed, InnerSession:%lu.", session_id_);
}

ret = model_executor_.Finalize();
if (ret != SUCCESS) {
// Subsequent code execution is required, so no return is required
GELOGE(ret, "[Finalize][GraphExecutor] failed, InnerSession:%lu.", session_id_);
REPORT_CALL_ERROR("E19999", "GraphExecutor Finalize failed, InnerSession:%lu.", session_id_);
}

return SUCCESS;
}

Status InnerSession::GetVariable(const std::string &name, Tensor &val) {
UpdateThreadContext(std::map<std::string, std::string>{});
return graph_manager_.GetVariable(name, val);


+ 5
- 0
ge/session/inner_session.h View File

@@ -23,6 +23,7 @@
#include "framework/common/ge_types.h"
#include "external/ge/ge_api_types.h"
#include "graph/manager/graph_manager.h"
#include "graph/execute/model_executor.h"

namespace ge {
class InnerSession {
@@ -82,10 +83,14 @@ class InnerSession {
void SetRtSocVersion();

private:
Status InnerInitialize();
Status InnerFinalize();

bool init_flag_;
uint64_t session_id_;
std::map<string, string> options_;
GraphManager graph_manager_;
ModelExecutor model_executor_;
std::mutex resource_mutex_; // AddGraph, RemoveGraph and Finalize use
void UpdateThreadContext(const std::map<std::string, std::string> &options);
void UpdateThreadContext(uint32_t graph_id);


+ 1
- 1
ge/single_op/task/op_task.h View File

@@ -268,7 +268,7 @@ class MemcpyAsyncTask : public OpTask {
friend class SingleOpModel;
friend class RtsKernelTaskBuilder;

uintptr_t addresses_[kAddressNum];
uintptr_t addresses_[kAddressNum] = {0};
size_t dst_max_;
size_t count_;
rtMemcpyKind_t kind_;


+ 4
- 1
tests/ut/ge/CMakeLists.txt View File

@@ -161,8 +161,9 @@ set(COMMON_SRC_FILES
"${GE_CODE_DIR}/ge/common/profiling/profiling_manager.cc"
"${GE_CODE_DIR}/ge/common/profiling/ge_profiling.cc"
"${GE_CODE_DIR}/ge/graph/manager/host_mem_manager.cc"
"${GE_CODE_DIR}/ge/graph/manager/memory_api.cc"
"${GE_CODE_DIR}/ge/graph/manager/memory_api.cc"
"${GE_CODE_DIR}/ge/session/inner_session.cc"
"${GE_CODE_DIR}/ge/graph/execute/model_executor.cc"
"${GE_CODE_DIR}/ge/graph/manager/util/rt_context_util.cc"
"${GE_CODE_DIR}/ge/graph/execute/graph_execute.cc"
"${GE_CODE_DIR}/ge/graph/preprocess/graph_preprocess.cc"
@@ -469,6 +470,7 @@ set(GRAPH_BUILD_COMMON_SRC_FILES
"${GE_CODE_DIR}/ge/client/ge_api.cc"
"${GE_CODE_DIR}/ge/session/inner_session.cc"
"${GE_CODE_DIR}/ge/session/session_manager.cc"
"${GE_CODE_DIR}/ge/graph/execute/model_executor.cc"
"${GE_CODE_DIR}/ge/engine_manager/dnnengine_manager.cc"
"${GE_CODE_DIR}/ge/plugin/engine/engine_manage.cc"
"${GE_CODE_DIR}/ge/graph/build/logical_stream_allocator.cc"
@@ -810,6 +812,7 @@ set(MULTI_PARTS_TEST_FILES
"graph/build/task_generator_unittest.cc"
"graph/build/buffer_pool_mem_assigner_unittest.cc"
"graph/execute/graph_execute_unittest.cc"
"graph/execute/model_executor_unittest.cc"
"graph/preprocess/graph_preprocess_unittest.cc"
"graph/manager/hcom_util_unittest.cc"
"graph/manager/graph_caching_allocator_unittest.cc"


+ 11
- 11
tests/ut/ge/common/datatype_transfer_unittest.cc View File

@@ -47,7 +47,7 @@ TEST_F(UtestDataTypeTransfer, fp16_fp32) {
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
bool is_equal = true;
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
if (abs((reinterpret_cast<float *>(result.data.get()))[i] - ret[i]) > 1.0e-6) {
is_equal = false;
break;
@@ -60,7 +60,7 @@ TEST_F(UtestDataTypeTransfer, fp16_fp32) {
CastArgs args2{reinterpret_cast<uint8_t *>(ret), sizeof(ret) / sizeof(ret[0]), DT_FLOAT, DT_FLOAT16};
EXPECT_EQ(transfer2.TransDataType(args2, result2), SUCCESS);
EXPECT_EQ(result2.length, sizeof(data));
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
EXPECT_FLOAT_EQ((reinterpret_cast<fp16_t *>(result2.data.get()))[i].val, data[i].val);
}
EXPECT_EQ(TransDataType(args2, result2), SUCCESS);
@@ -81,7 +81,7 @@ TEST_F(UtestDataTypeTransfer, int32_fp16) {
CastArgs args{reinterpret_cast<uint8_t *>(data), sizeof(ret) / sizeof(ret[0]), DT_INT32, DT_FLOAT16};
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
EXPECT_FLOAT_EQ((reinterpret_cast<fp16_t *>(result.data.get()))[i].val, ret[i].val);
}

@@ -91,7 +91,7 @@ TEST_F(UtestDataTypeTransfer, int32_fp16) {
EXPECT_EQ(transfer2.TransDataType(args2, result2), SUCCESS);
EXPECT_EQ(result2.length, sizeof(data));
bool is_equal = true;
for (int i = 0; i < sizeof(data) / sizeof(data[0]); ++i) {
for (size_t i = 0; i < sizeof(data) / sizeof(data[0]); ++i) {
if (abs((reinterpret_cast<int32_t *>(result2.data.get()))[i] - data[i]) / abs(data[i]) > 0.05) {
is_equal = false;
break;
@@ -154,7 +154,7 @@ TEST_F(UtestDataTypeTransfer, fp32_fp16) {
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
bool is_equal = true;
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
if (abs((reinterpret_cast<float *>(result.data.get()))[i] - ret[i]) > 1.0e-6) {
is_equal = false;
break;
@@ -167,7 +167,7 @@ TEST_F(UtestDataTypeTransfer, fp32_fp16) {
CastArgs args2{reinterpret_cast<uint8_t *>(ret), sizeof(data) / sizeof(data[0]), DT_FLOAT, DT_FLOAT16};
EXPECT_EQ(transfer2.TransDataType(args2, result2), SUCCESS);
EXPECT_EQ(result2.length, sizeof(data));
for (int i = 0; i < sizeof(data) / sizeof(data[0]); ++i) {
for (size_t i = 0; i < sizeof(data) / sizeof(data[0]); ++i) {
EXPECT_FLOAT_EQ((reinterpret_cast<fp16_t *>(result2.data.get()))[i].val, data[i].val);
}
}
@@ -238,7 +238,7 @@ TEST_F(UtestDataTypeTransfer, uint8_fp32) {
DataTypeTransfer transfer;
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
EXPECT_EQ((reinterpret_cast<float *>(result.data.get()))[i], ret[i]);
}
}
@@ -259,7 +259,7 @@ TEST_F(UtestDataTypeTransfer, uint8_int32) {
DataTypeTransfer transfer;
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
EXPECT_EQ((reinterpret_cast<int32_t *>(result.data.get()))[i], ret[i]);
}
}
@@ -282,7 +282,7 @@ TEST_F(UtestDataTypeTransfer, fp32_int32) {
DataTypeTransfer transfer;
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
EXPECT_FLOAT_EQ((reinterpret_cast<int32_t *>(result.data.get()))[i], ret[i]);
}
}
@@ -304,7 +304,7 @@ TEST_F(UtestDataTypeTransfer, int32_fp32) {
DataTypeTransfer transfer;
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
EXPECT_FLOAT_EQ((reinterpret_cast<float *>(result.data.get()))[i], ret[i]);
}
}
@@ -329,7 +329,7 @@ TEST_F(UtestDataTypeTransfer, int32_uint8) {
DataTypeTransfer transfer;
EXPECT_EQ(transfer.TransDataType(args, result), SUCCESS);
EXPECT_EQ(result.length, sizeof(ret));
for (int i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
for (size_t i = 0; i < sizeof(ret) / sizeof(ret[0]); ++i) {
EXPECT_FLOAT_EQ((reinterpret_cast<uint8_t *>(result.data.get()))[i], ret[i]);
}
}


+ 327
- 0
tests/ut/ge/graph/execute/model_executor_unittest.cc View File

@@ -0,0 +1,327 @@
/**
* Copyright 2021 Huawei Technologies Co., Ltd
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* 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 <gtest/gtest.h>

#define protected public
#define private public
#include "graph/execute/model_executor.h"
#include "graph/manager/graph_manager.h"
#include "graph/load/model_manager/model_manager.h"
#include "graph/load/model_manager/davinci_model.h"

using namespace std;

namespace ge {
class UtestModelExecutorTest : public testing::Test {
protected:
void SetUp() {}
void TearDown() {}
};

static NodePtr CreateNode(ComputeGraph &graph, const string &name, const string &type, int in_num, int out_num) {
OpDescPtr op_desc = std::make_shared<OpDesc>(name, type);
op_desc->SetStreamId(0);
static int32_t index = 0;
op_desc->SetId(index++);

GeTensorDesc tensor(GeShape(), FORMAT_ND, DT_INT64);
TensorUtils::SetSize(tensor, 64);
vector<int64_t> input_offset;
for (int i = 0; i < in_num; i++) {
op_desc->AddInputDesc(tensor);
input_offset.emplace_back(index * 64 + i * 64);
}
op_desc->SetInputOffset(input_offset);

vector<int64_t> output_offset;
for (int i = 0; i < out_num; i++) {
op_desc->AddOutputDesc(tensor);
output_offset.emplace_back(index * 64 + in_num * 64 + i * 64);
}
op_desc->SetOutputOffset(output_offset);

op_desc->SetWorkspace({});
op_desc->SetWorkspaceBytes({});
op_desc->SetOpKernelLibName("DNN_VM_RTS_OP_STORE");

return graph.AddNode(op_desc);
}

TEST_F(UtestModelExecutorTest, test_load_graph_sync) {
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

auto compute_graph = MakeShared<ComputeGraph>("test_graph");
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);

GeModelPtr ge_model = MakeShared<GeModel>();
ge_model->SetGraph(GraphUtils::CreateGraphFromComputeGraph(compute_graph));
ge_root_model->SetSubgraphInstanceNameToModel(compute_graph->GetName(), ge_model);

GraphId graph_id = 1;
GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(true);
graph_node->SetAsync(false);

EXPECT_EQ(model_executor.LoadGraph(ge_root_model, graph_node), SUCCESS);
EXPECT_EQ(model_executor.UnloadGraph(ge_root_model, graph_id), SUCCESS);

EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

TEST_F(UtestModelExecutorTest, test_load_graph_async) {
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

Graph graph("test_graph");
auto compute_graph = MakeShared<ComputeGraph>("test_graph");
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);

GeModelPtr ge_model = MakeShared<GeModel>();
ge_model->SetGraph(GraphUtils::CreateGraphFromComputeGraph(compute_graph));
ge_root_model->SetSubgraphInstanceNameToModel(compute_graph->GetName(), ge_model);

GraphId graph_id = 1;
GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(true);
graph_node->SetAsync(true);

EXPECT_EQ(model_executor.LoadGraph(ge_root_model, graph_node), SUCCESS);

EXPECT_EQ(model_executor.UnloadGraph(ge_root_model, graph_id), SUCCESS);

EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

TEST_F(UtestModelExecutorTest, test_load_graph_failed) {
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

Graph graph("test_graph");
auto compute_graph = MakeShared<ComputeGraph>("test_graph");
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);

GraphId graph_id = 1;
GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(true);
graph_node->SetAsync(true);

// GeModel is null, DavinciModel::Assign will return FAILED
setenv(kEnvGeuseStaticMemory, "1", true);
EXPECT_EQ(model_executor.LoadGraph(ge_root_model, graph_node), FAILED);
EXPECT_EQ(model_executor.UnloadGraph(ge_root_model, graph_id), SUCCESS);

EXPECT_EQ(model_executor.Finalize(), SUCCESS);
unsetenv(kEnvGeuseStaticMemory);
}

TEST_F(UtestModelExecutorTest, test_check_and_release_memory) {
{
auto listener = MakeShared<RunAsyncListener>();
shared_ptr<DavinciModel> davinci_model1 = MakeShared<DavinciModel>(1, listener);
davinci_model1->SetId(1);
ModelManager::GetInstance()->InsertModel(1, davinci_model1);
shared_ptr<DavinciModel> davinci_model2 = MakeShared<DavinciModel>(2, listener);
davinci_model1->SetId(2);
ModelManager::GetInstance()->InsertModel(2, davinci_model2);
}

ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

GeModelPtr ge_model = make_shared<GeModel>();
int64_t memory_size = 25 * 1024UL * 1024UL * 1024UL;
int64_t weight_size = 25 * 1024UL * 1024UL * 1024UL;
uint64_t session_id = 0;
EXPECT_TRUE(AttrUtils::SetInt(ge_model, ATTR_MODEL_MEMORY_SIZE, memory_size));
EXPECT_TRUE(AttrUtils::SetInt(ge_model, ATTR_MODEL_WEIGHT_SIZE, weight_size));
EXPECT_TRUE(AttrUtils::SetInt(ge_model, MODEL_ATTR_SESSION_ID, session_id));

GraphId graph_id = 1;
GraphNodePtr graph_node = MakeShared<GraphNode>(graph_id);
model_executor.AddGraphNode(graph_id, graph_node);

ComputeGraphPtr compute_graph = MakeShared<ComputeGraph>("test_graph");
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);
ge_root_model->SetModelId(1);
ge_root_model->SetModelId(2);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(true);

EXPECT_EQ(model_executor.CheckAndReleaseMemory(ge_model, graph_node), SUCCESS);
EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

TEST_F(UtestModelExecutorTest, parse_inputs_dims_data) {
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

OmeContext context;
SetLocalOmeContext(context);
ComputeGraphPtr compute_graph = MakeShared<ComputeGraph>("test_graph");
const auto data1 = CreateNode(*compute_graph, DATA, "data1", 1, 1);
const auto next1 = CreateNode(*compute_graph, GETNEXT, "data1", 1, 1);

Tensor tensor;
std::vector<Tensor> input_tensors;
input_tensors.emplace_back(tensor);
EXPECT_EQ(model_executor.ParseInputsDims(input_tensors), SUCCESS); // dynamic_node_type is empty, just return

context.dynamic_node_type = DATA;
EXPECT_EQ(model_executor.ParseInputsDims(input_tensors), SUCCESS); // ParseInputsDimsForData

context.getnext_nosink_nodes.emplace_back(next1);
EXPECT_EQ(model_executor.ParseInputsDims(input_tensors), SUCCESS); // ParseInputsDimsForGetNexNosinkAndData

EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

TEST_F(UtestModelExecutorTest, parse_inputs_dims_getnext) {
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

OmeContext context;
SetLocalOmeContext(context);
ComputeGraphPtr compute_graph = MakeShared<ComputeGraph>("test_graph");
const auto data1 = CreateNode(*compute_graph, DATA, "data1", 1, 1);
const auto next1 = CreateNode(*compute_graph, GETNEXT, "data1", 1, 1);

Tensor tensor;
std::vector<Tensor> input_tensors;
input_tensors.emplace_back(tensor);

context.dynamic_node_type = GETNEXT;
EXPECT_EQ(model_executor.ParseInputsDims(input_tensors), SUCCESS); // just getnext_sink

context.getnext_nosink_nodes.emplace_back(next1);
EXPECT_EQ(model_executor.ParseInputsDims(input_tensors), SUCCESS); // ParseInputsDimsForData

context.data_nodes.emplace_back(data1);
EXPECT_EQ(model_executor.ParseInputsDims(input_tensors), PARAM_INVALID); // ParseInputsDimsForGetNexNosinkAndData
AttrUtils::SetInt(next1->GetOpDesc(), ATTR_NAME_INDEX, 0);
EXPECT_EQ(model_executor.ParseInputsDims(input_tensors), SUCCESS); // ParseInputsDimsForGetNexNosinkAndData

EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

TEST_F(UtestModelExecutorTest, test_run_thread) {
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

GraphId graph_id = 1;
uint64_t session_id = 0;
error_message::Context error_context;
GEThreadLocalContext context;
const auto callback = [](Status status, std::vector<ge::Tensor> &outputs) { };

auto compute_graph = MakeShared<ComputeGraph>("test_graph");
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);

GeModelPtr ge_model = MakeShared<GeModel>();
ge_model->SetGraph(GraphUtils::CreateGraphFromComputeGraph(compute_graph));
ge_root_model->SetSubgraphInstanceNameToModel(compute_graph->GetName(), ge_model);

GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(false);
graph_node->SetAsync(true);
graph_node->IncreaseLoadCount();
graph_node->Lock();

Tensor tensor;
std::vector<Tensor> input_tensors;
input_tensors.emplace_back(tensor);

RunArgs run_args{graph_node, graph_id, session_id, error_context, input_tensors, ge_root_model, context, callback};
EXPECT_EQ(model_executor.PushGraph(run_args), SUCCESS);

while (model_executor.run_args_q_.Size() > 0) {
usleep(10); // 0.01ms, Wait for RunThread.
}
EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

static void test_run_graph(ModelExecutor &model_executor) {
auto compute_graph = MakeShared<ComputeGraph>("test_graph");
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);

GeModelPtr ge_model = MakeShared<GeModel>();
ge_model->SetGraph(GraphUtils::CreateGraphFromComputeGraph(compute_graph));
ge_root_model->SetSubgraphInstanceNameToModel(compute_graph->GetName(), ge_model);

GraphId graph_id = 1;
GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(false);
graph_node->SetAsync(false); // RunGraph is Synchronization.
EXPECT_EQ(model_executor.LoadGraph(ge_root_model, graph_node), SUCCESS);

std::vector<GeTensor> inputs;
std::vector<GeTensor> outputs;
EXPECT_EQ(model_executor.RunGraph(graph_node, graph_id, inputs, outputs), SUCCESS);
}

TEST_F(UtestModelExecutorTest, test_run_graph_train) {
GetThreadLocalContext().SetGlobalOption({{OPTION_GRAPH_RUN_MODE, "1"}});
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);
test_run_graph(model_executor);
EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

TEST_F(UtestModelExecutorTest, test_run_graph_infer) {
GetThreadLocalContext().SetGlobalOption({});
GetThreadLocalContext().SetSessionOption({});
GetThreadLocalContext().SetGraphOption({});
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);
test_run_graph(model_executor);
EXPECT_EQ(model_executor.Finalize(), SUCCESS);
}

TEST_F(UtestModelExecutorTest, test_run_graph_with_stream) {
ModelExecutor model_executor;
EXPECT_EQ(model_executor.Initialize({}), SUCCESS);

GraphId graph_id = 1;
auto compute_graph = MakeShared<ComputeGraph>("test_graph");
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);

GeModelPtr ge_model = MakeShared<GeModel>();
ge_model->SetGraph(GraphUtils::CreateGraphFromComputeGraph(compute_graph));
ge_root_model->SetSubgraphInstanceNameToModel(compute_graph->GetName(), ge_model);

GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(false);
graph_node->SetAsync(true);

GeTensor tensor;
std::vector<GeTensor> inputs{tensor};
std::vector<GeTensor> outputs;

rtStream_t stream = nullptr;
rtStreamCreate(&stream, 0);
EXPECT_EQ(model_executor.RunGraphWithStream(graph_node, graph_id, stream, inputs, outputs), 145003);

EXPECT_EQ(model_executor.Finalize(), SUCCESS);
rtStreamDestroy(stream);
}
} // namespace ge

+ 48
- 76
tests/ut/ge/graph/manager/graph_manager_unittest.cc View File

@@ -15,20 +15,9 @@
*/

#include <gtest/gtest.h>

#include <memory>
#include <stdlib.h>
#define protected public
#define private public
#include "graph/manager/graph_manager.h"
#include "graph/load/model_manager/model_manager.h"
#include "graph/load/model_manager/davinci_model.h"
#define const
#include "common/helper/model_cache_helper.h"
#undef const
#include "init/gelib.h"
#undef private
#undef public

#include <pthread.h>
#include <algorithm>
#include <future>
@@ -38,6 +27,14 @@
#include <thread>
#include <future>

#define protected public
#define private public
#include "graph/manager/graph_manager.h"
#define const
#include "common/helper/model_cache_helper.h"
#undef const
#include "init/gelib.h"

#include "common/math/math_util.h"
#include "common/thread_pool.h"
#include "common/dump/dump_manager.h"
@@ -121,7 +118,6 @@

using namespace std;
using namespace testing;
using namespace ge;
using namespace domi;

namespace {
@@ -129,6 +125,8 @@ const uint32_t kNotAdded = 0;
const uint32_t kStartAdd = 1;
const uint32_t kDoneAdded = 2;
}

namespace ge {
class UtestGraphManagerTest : public testing::Test {
protected:
void SetUp() {}
@@ -136,6 +134,31 @@ class UtestGraphManagerTest : public testing::Test {
void TearDown() {}
};

class StubExecutor : public Executor {
public:
Status LoadGraph(const GeRootModelPtr &ge_root_model, const GraphNodePtr &graph_node) {
return SUCCESS;
}

Status UnloadGraph(const GeRootModelPtr &ge_root_model, uint32_t graph_id) {
return SUCCESS;
}

Status PushGraph(const RunArgs &args) {
return SUCCESS;
}

Status RunGraph(const GraphNodePtr &graph_node, GraphId graph_id,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs) {
return SUCCESS;
}

Status RunGraphWithStream(const GraphNodePtr &graph_node, GraphId graph_id, rtStream_t stream,
const std::vector<GeTensor> &inputs, std::vector<GeTensor> &outputs){
return SUCCESS;
}
};

void CreateGraph(Graph &graph) {
TensorDesc desc(ge::Shape({1, 3, 224, 224}));
uint32_t size = desc.GetShape().GetShapeSize();
@@ -288,26 +311,20 @@ TEST_F(UtestGraphManagerTest, test_remove_graph_1) {
TEST_F(UtestGraphManagerTest, test_remove_graph_2) {
GraphId graph_id = 1;
GraphManager graph_manager;
StubExecutor stub_executor;
graph_manager.executor_ = &stub_executor;

GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
Graph graph("test_graph");
CreateGraph(graph);
auto compute_graph = GraphUtils::GetComputeGraph(graph);
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);
auto model_manager = ModelManager::GetInstance();
auto listener = MakeShared<RunAsyncListener>();
shared_ptr<DavinciModel> davinci_model1 = MakeShared<DavinciModel>(1, listener);
davinci_model1->SetId(1);
shared_ptr<DavinciModel> davinci_model2 = MakeShared<DavinciModel>(2, listener);
davinci_model1->SetId(2);
model_manager->InsertModel(1, davinci_model1);
model_manager->InsertModel(2, davinci_model2);
ge_root_model->SetModelId(1);
ge_root_model->SetModelId(2);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(true);
graph_manager.AddGraphNode(graph_id, graph_node);
Status status = graph_manager.RemoveGraph(graph_id);
EXPECT_EQ(status, ge::SUCCESS);
EXPECT_EQ(graph_manager.RemoveGraph(graph_id), SUCCESS);
}

TEST_F(UtestGraphManagerTest, test_pre_run_thread) {
@@ -327,7 +344,7 @@ TEST_F(UtestGraphManagerTest, test_pre_run_thread) {

GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_manager.AddGraphNode(graph_id, graph_node);
graph_manager.PreRunThread(&graph_manager);
graph_manager.PreRunThread();
// end with failed
}

@@ -355,48 +372,10 @@ TEST_F(UtestGraphManagerTest, test_pre_run_thread_2) {
graph_manager.AddGraphNode(graph_id, graph_node_2);
ret = graph_manager.prerun_args_q_.Push({graph_id, input_tensor, session_id, error_context, context, callback});
EXPECT_EQ(ret, true);
graph_manager.PreRunThread(&graph_manager);
graph_manager.PreRunThread();
// end with failed
}

TEST_F(UtestGraphManagerTest, test_check_and_release_memory) {
GraphManager graph_manager;
GeModelPtr ge_model = make_shared<GeModel>();
int64_t memory_size = 25 * 1024UL * 1024UL * 1024UL;
int64_t weight_size = 25 * 1024UL * 1024UL * 1024UL;
uint64_t session_id = 0;
ge::AttrUtils::SetInt(ge_model, ATTR_MODEL_MEMORY_SIZE, memory_size);
ge::AttrUtils::SetInt(ge_model, ATTR_MODEL_WEIGHT_SIZE, weight_size);
ge::AttrUtils::SetInt(ge_model, MODEL_ATTR_SESSION_ID, session_id);

GraphId graph_id = 1;
GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_manager.AddGraphNode(graph_id, graph_node);
graph_manager.IncreaseGraphCount(graph_id);
graph_manager.IncreaseGraphCount(graph_id);

auto model_manager = ModelManager::GetInstance();
auto listener = MakeShared<RunAsyncListener>();
shared_ptr<DavinciModel> davinci_model1 = MakeShared<DavinciModel>(1, listener);
davinci_model1->SetId(1);
shared_ptr<DavinciModel> davinci_model2 = MakeShared<DavinciModel>(2, listener);
davinci_model1->SetId(2);
model_manager->InsertModel(1, davinci_model1);
model_manager->InsertModel(2, davinci_model2);
ComputeGraphPtr compute_graph = MakeShared<ComputeGraph>("test_graph");
bool is_dynamic_shape = false;
(void)AttrUtils::GetBool(compute_graph, ATTR_NAME_DYNAMIC_SHAPE_PARTITIONED, is_dynamic_shape);
GeRootModelPtr ge_root_model = MakeShared<GeRootModel>(compute_graph);
ge_root_model->SetModelId(1);
ge_root_model->SetModelId(2);
graph_node->SetGeRootModel(ge_root_model);
graph_node->SetLoadFlag(true);
Status status = graph_manager.CheckAndReleaseMemory(ge_model, graph_node);
EXPECT_EQ(status, ge::SUCCESS);
}

TEST_F(UtestGraphManagerTest, test_check_incre_build_and_pre_run_1) {
// no need to build
GraphId graph_id = 1;
@@ -406,7 +385,7 @@ TEST_F(UtestGraphManagerTest, test_check_incre_build_and_pre_run_1) {
GraphManager::PreRunArgs arg;
GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetBuildFlag(true);
Status status = graph_manager.CheckIncreBuildAndPreRun(&graph_manager, arg, graph_node, ge_root_model);
Status status = graph_manager.CheckIncreBuildAndPreRun(arg, graph_node, ge_root_model);
EXPECT_EQ(status, ge::SUCCESS);
}

@@ -422,7 +401,7 @@ TEST_F(UtestGraphManagerTest, test_check_incre_build_and_pre_run_2) {
graph_node->SetBuildFlag(true);
graph_node->Lock();
graph_manager.var_acc_ctrl_.graph_ids_need_rebuild_.insert(graph_id);
Status status = graph_manager.CheckIncreBuildAndPreRun(&graph_manager, arg, graph_node, ge_root_model);
Status status = graph_manager.CheckIncreBuildAndPreRun(arg, graph_node, ge_root_model);
EXPECT_EQ(status, ge::PARAM_INVALID);
}

@@ -437,7 +416,7 @@ TEST_F(UtestGraphManagerTest, test_check_incre_build_and_pre_run_3) {
GraphNodePtr graph_node = MakeShared<ge::GraphNode>(graph_id);
graph_node->SetBuildFlag(false);
graph_node->Lock();
Status status = graph_manager.CheckIncreBuildAndPreRun(&graph_manager, arg, graph_node, ge_root_model);
Status status = graph_manager.CheckIncreBuildAndPreRun(arg, graph_node, ge_root_model);
EXPECT_NE(status, ge::SUCCESS);
}

@@ -471,14 +450,6 @@ TEST_F(UtestGraphManagerTest, test_add_graph_with_copy_fail) {
EXPECT_NE(status, ge::SUCCESS);
}

TEST_F(UtestGraphManagerTest, ParseInputsDimsForData_success) {
GraphManager graph_manager;
std::vector<ge::Tensor> input_tensors;
ge::Tensor tensor;
input_tensors.emplace_back(tensor);
graph_manager.ParseInputsDimsForData(input_tensors);
}

TEST_F(UtestGraphManagerTest, test_prerunthread_failed_1) {
GraphId graph_id = 1;
GraphManager graph_manager;
@@ -509,7 +480,7 @@ TEST_F(UtestGraphManagerTest, test_prerunthread_failed_1) {
graph_node->SetRunFlag(false);
// function return.
graph_manager.prerun_args_q_.Push(args);
auto t1 = std::thread(GraphManager::PreRunThread, &graph_manager);
auto t1 = std::thread(&GraphManager::PreRunThread, &graph_manager);
if (t1.joinable()) {
t1.join();
}
@@ -549,7 +520,7 @@ TEST_F(UtestGraphManagerTest, test_prerunthread_failed_2) {
int ret = setenv("ENABLE_NETWORK_ANALYSIS_DEBUG", "1", 1);
EXPECT_EQ(ret, 0);
graph_manager.prerun_args_q_.Push(args);
auto t1 = std::thread(GraphManager::PreRunThread, &graph_manager);
auto t1 = std::thread(&GraphManager::PreRunThread, &graph_manager);
if (t1.joinable()) {
t1.join();
}
@@ -593,3 +564,4 @@ TEST_F(UtestGraphManagerTest, ChangeAndDeleteConst_success) {
auto all_nodes = graph->GetDirectNode();
EXPECT_EQ(all_nodes.size(), 3);
}
} // namespace ge

+ 16
- 16
tests/ut/ge/graph/passes/folding_kernel/gather_v2_kernel_unittest.cc View File

@@ -92,7 +92,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT32Axis0VersionA) {
GeTensorPtr tensor_out = outputs[0];
int32_t *data_buf = (int32_t *)tensor_out->GetData().data();
vector<int32_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -139,7 +139,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT32Axis0VersionB) {
GeTensorPtr tensor_out = outputs[0];
int32_t *data_buf = (int32_t *)tensor_out->GetData().data();
vector<int32_t> expect_out = {3, 3};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -186,7 +186,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT64Axis0) {
GeTensorPtr tensor_out = outputs[0];
int64_t *data_buf = (int64_t *)tensor_out->GetData().data();
vector<int64_t> expect_out = {3, 3};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -233,7 +233,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT32Axis0) {
GeTensorPtr tensor_out = outputs[0];
int32_t *data_buf = (int32_t *)tensor_out->GetData().data();
vector<int32_t> expect_out = {11, 12, 13, 14, 15, 16, 17, 18, 19, 11, 12, 13, 14, 15, 16, 17, 18, 19};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -279,7 +279,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT32Axis0And1) {
GeTensorPtr tensor_out = outputs[0];
int32_t *data_buf = (int32_t *)tensor_out->GetData().data();
vector<int32_t> expect_out = {11, 12, 13, 14, 15, 16, 17, 18, 19, 1, 2, 3, 4, 5, 6, 7, 8, 9};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -327,7 +327,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT32Axis1) {
GeTensorPtr tensor_out = outputs[0];
int32_t *data_buf = (int32_t *)tensor_out->GetData().data();
vector<int32_t> expect_out = {4, 5, 6, 4, 5, 6, 14, 15, 16, 14, 15, 16};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -374,7 +374,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT32Axis2) {
GeTensorPtr tensor_out = outputs[0];
int32_t *data_buf = (int32_t *)tensor_out->GetData().data();
vector<int32_t> expect_out = {1, 1, 4, 4, 7, 7, 11, 11, 14, 14, 17, 17};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -422,7 +422,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT32Axis3) {
GeTensorPtr tensor_out = outputs[0];
int32_t *data_buf = (int32_t *)tensor_out->GetData().data();
vector<int32_t> expect_out = {1, 2, 4, 5, 7, 8, 11, 12, 14, 15, 17, 18, 1, 2, 4, 5, 7, 8, 11, 12, 14, 15, 17, 18};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -470,7 +470,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT8Axis0) {
GeTensorPtr tensor_out = outputs[0];
int8_t *data_buf = (int8_t *)tensor_out->GetData().data();
vector<int8_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -517,7 +517,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, INT16Axis0) {
GeTensorPtr tensor_out = outputs[0];
int16_t *data_buf = (int16_t *)tensor_out->GetData().data();
vector<int16_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -564,7 +564,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, UINT8Axis0) {
GeTensorPtr tensor_out = outputs[0];
uint8_t *data_buf = (uint8_t *)tensor_out->GetData().data();
vector<uint8_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -611,7 +611,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, UINT16Axis0) {
GeTensorPtr tensor_out = outputs[0];
uint16_t *data_buf = (uint16_t *)tensor_out->GetData().data();
vector<uint16_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -658,7 +658,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, UINT32Axis0) {
GeTensorPtr tensor_out = outputs[0];
uint32_t *data_buf = (uint32_t *)tensor_out->GetData().data();
vector<uint32_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -705,7 +705,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, UINT64Axis0) {
GeTensorPtr tensor_out = outputs[0];
uint64_t *data_buf = (uint64_t *)tensor_out->GetData().data();
vector<uint64_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
EXPECT_EQ(*(data_buf + i), expect_out[i]);
}
}
@@ -753,7 +753,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, DoubleAxis0) {
GeTensorPtr tensor_out = outputs[0];
double *data_buf = (double *)tensor_out->GetData().data();
vector<double> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
double diff = *(data_buf + i) - expect_out[i];
bool is_same = fabs(diff) < 0.0001 ? true : false;
EXPECT_EQ(is_same, true);
@@ -802,7 +802,7 @@ TEST_F(UtestGraphPassesFoldingKernelGatherV2Kernel, Float16Axis0) {
GeTensorPtr tensor_out = outputs[0];
fp16_t *data_buf = (fp16_t *)tensor_out->GetData().data();
vector<fp16_t> expect_out = {2, 2};
for (int i = 0; i < expect_out.size(); i++) {
for (size_t i = 0; i < expect_out.size(); i++) {
double diff = (double)*(data_buf + i) - (double)expect_out[i];
bool is_same = fabs(diff) < 0.0001 ? true : false;
EXPECT_EQ(is_same, true);


+ 1
- 1
tests/ut/ge/graph/passes/mark_node_unknown_shape_pass_unittest.cc View File

@@ -33,7 +33,7 @@ protected:
void SetUp() {}
void TearDown() {}
public:
NodePtr MakeNode(const ComputeGraphPtr &graph, uint32_t in_num, uint32_t out_num, string name, string type) {
NodePtr MakeNode(const ComputeGraphPtr &graph, int in_num, int out_num, string name, string type) {
GeTensorDesc test_desc(GeShape(), FORMAT_NCHW, DT_FLOAT);
auto op_desc = std::make_shared<OpDesc>(name, type);
for (auto i = 0; i < in_num; ++i) {


+ 1
- 1
tests/ut/ge/graph/passes/multi_batch_clone_pass_unittest.cc View File

@@ -45,7 +45,7 @@ protected:
}

public:
NodePtr MakeNode(const ComputeGraphPtr &graph, uint32_t in_num, uint32_t out_num, string name, string type) {
NodePtr MakeNode(const ComputeGraphPtr &graph, int in_num, int out_num, string name, string type) {
GeTensorDesc test_desc(GeShape(), FORMAT_NCHW, DT_FLOAT);
auto op_desc = std::make_shared<OpDesc>(name, type);
for (auto i = 0; i < in_num; ++i) {


+ 1
- 1
tests/ut/ge/graph/passes/subgraph_const_migration_pass_unittest.cc View File

@@ -32,7 +32,7 @@ class UtestSubgraphConstMigrationPass : public testing::Test {
void TearDown() {}

public:
NodePtr MakeNode(const ComputeGraphPtr &graph, uint32_t in_num, uint32_t out_num, string name, string type) {
NodePtr MakeNode(const ComputeGraphPtr &graph, int in_num, int out_num, string name, string type) {
GeTensorDesc test_desc(GeShape(), FORMAT_NCHW, DT_FLOAT);
auto op_desc = std::make_shared<OpDesc>(name, type);
for (auto i = 0; i < in_num; ++i) {


+ 7
- 12
tests/ut/ge/session/inner_session_unittest.cc View File

@@ -19,21 +19,18 @@
#define private public
#define protected public
#include "session/inner_session.h"
#undef private
#undef protected
using namespace std;
namespace ge {
class Utest_Inner_session : public testing::Test {
class UtestInnerSession : public testing::Test {
protected:
void SetUp() override {}
void TearDown() override {}
};
TEST_F(Utest_Inner_session, build_graph_success) {
TEST_F(UtestInnerSession, build_graph_success) {
std::map <string, string> options;
uint64_t session_id = 1;
InnerSession inner_seesion(session_id, options);
@@ -44,17 +41,15 @@ TEST_F(Utest_Inner_session, build_graph_success) {
EXPECT_NE(ret, ge::SUCCESS);
}
TEST_F(Utest_Inner_session, initialize) {
std::map<std::string, std::string> options = {
{ge::MODIFY_MIXLIST, "/modify.json"}
};
TEST_F(UtestInnerSession, initialize) {
std::map<std::string, std::string> options = {};
uint64_t session_id = 1;
InnerSession inner_session(session_id, options);
auto ret = inner_session.Initialize();
EXPECT_NE(ret, ge::SUCCESS);
EXPECT_EQ(inner_session.Initialize(), SUCCESS);
EXPECT_EQ(inner_session.Finalize(), SUCCESS);
}
TEST_F(Utest_Inner_session, check_op_precision_mode) {
TEST_F(UtestInnerSession, check_op_precision_mode) {
std::map<std::string, std::string> options = {
{ge::OP_PRECISION_MODE, "./op_precision_mode.ini"}
};


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