Support session scope memory

4 years ago · aa579530fb
--- a/ge/CMakeLists.txt
+++ b/ge/CMakeLists.txt
@@ -173,10 +173,12 @@ set(TRAIN_SRC_LIST
    "graph/manager/graph_manager_utils.cc"
    "graph/manager/graph_mem_allocator.cc"
    "graph/manager/graph_caching_allocator.cc"
    "graph/manager/session_scope_mem_allocator.cc"
    "graph/manager/graph_var_manager.cc"
    "graph/manager/host_mem_manager.cc"
    "graph/manager/rdma_pool_allocator.cc"
    "graph/manager/host_mem_allocator.cc"
    "graph/manager/graph_mem_manager.cc"
    "graph/manager/memory_api.cc"
    "graph/manager/model_manager/event_manager.cc"
    "graph/manager/trans_var_data_utils.cc"
@@ -478,6 +480,8 @@ set(INFER_SRC_LIST
    "graph/manager/host_mem_allocator.cc"
    "graph/manager/graph_mem_allocator.cc"
    "graph/manager/graph_caching_allocator.cc"
    "graph/manager/session_scope_mem_allocator.cc"
    "graph/manager/graph_mem_manager.cc"
    "model/ge_model.cc"
    "model/ge_root_model.cc"
    "graph/common/transop_util.cc"
--- a/ge/executor/CMakeLists.txt
+++ b/ge/executor/CMakeLists.txt
@@ -28,6 +28,8 @@ set(SRC_LIST
    "../graph/manager/graph_var_manager.cc"
    "../graph/manager/graph_mem_allocator.cc"
    "../graph/manager/graph_caching_allocator.cc"
    "../graph/manager/session_scope_mem_allocator.cc"
    "../graph/manager/graph_mem_manager.cc"
    "../graph/manager/trans_var_data_utils.cc"
    "../graph/manager/util/debug.cc"
    "../graph/manager/rdma_pool_allocator.cc"
--- a/ge/executor/ge_executor.cc
+++ b/ge/executor/ge_executor.cc
@@ -26,7 +26,7 @@
 #include "graph/execute/graph_execute.h"
 #include "graph/load/graph_loader.h"
 #include "graph/load/model_manager/model_manager.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "single_op/single_op_manager.h"
 #include "graph/load/model_manager/davinci_model.h"
 #include "opskernel_manager/ops_kernel_builder_manager.h"
--- a/ge/graph/build/memory/block_mem_assigner.cc
+++ b/ge/graph/build/memory/block_mem_assigner.cc
@@ -500,6 +500,7 @@ string MemoryBlock::String() {
  ss << "Block size: " << Size() << " from " << HeadOffset() << " to " << TailOffset() << " ";
  ss << "real_size_list: " << ToString(real_size_list_) << " ";
  ss << "ref_count: " << ref_count_ << " ";
  ss << "reuse_mem_: " << reuse_mem_ << " ";
  ss << "members: ";
  for (auto x : NodeTypeIndexList()) {
    ss << "__node: " << ToString(x) << " ";
@@ -513,8 +514,8 @@ string MemoryBlock::String() {

 BlockMemAssigner::BlockMemAssigner(ComputeGraphPtr compute_graph, const map<string, string> &anchor_to_symbol,
                                   const map<string, list<NodeIndexIO>> &symbol_to_anchors)
    : mem_offset_(0), p2p_mem_offset_(0), compute_graph_(std::move(compute_graph)),
      symbol_to_anchors_(symbol_to_anchors), anchor_to_symbol_(anchor_to_symbol), life_time_(0) {}
    : compute_graph_(std::move(compute_graph)), symbol_to_anchors_(symbol_to_anchors),
      anchor_to_symbol_(anchor_to_symbol), life_time_(0) {}

 BlockMemAssigner::~BlockMemAssigner() {
  GELOGD("[Destruct][BlockMemAssigner]blocks_store_ size : %lu", blocks_store_.size());
@@ -1123,7 +1124,7 @@ bool BlockMemAssigner::IsZeroCopyBlock(const NodePtr &node, bool continuous) {
 MemoryBlock *BlockMemAssigner::ApplyMemory(size_t block_size, size_t real_size, size_t no_align_size,
                                           OpMemoryType mem_type, const NodePtr &n, uint32_t out_index,
                                           const vector<bool> &workspace_reuse_flag, const bool is_op_reuse_mem,
                                           const bool continuous, int64_t memory_type) {
                                           const bool continuous, uint64_t memory_type) {
  GE_CHK_BOOL_TRUE_EXEC_WITH_LOG(
      n == nullptr,
      REPORT_INNER_ERROR("E19999", "Input parameter n(type:node_ptr) is null, apply memory failed");
@@ -1824,8 +1825,8 @@ void BlockMemAssigner::AssignMemoryWithReuse(vector<int64_t> &ranges) {
        zero_memory_list_.emplace_back(n, kWorkspace, static_cast<uint32_t>(i), false);
        continue;
      }
      int64_t memory_type = RT_MEMORY_HBM;
      if (!GetWorkSpaceMemoryType(n, i, memory_type)) {
      uint64_t memory_type = RT_MEMORY_HBM;
      if (!GetWorkSpaceMemoryType(n, i, memory_type, workspace_reuse_flag)) {
        GELOGW("Get workspace memory type failed.");
        return;
      }
@@ -1860,7 +1861,7 @@ void BlockMemAssigner::AssignMemoryWithReuse(vector<int64_t> &ranges) {
 }

 void BlockMemAssigner::CheckWorkspaceReuse(const vector<bool> &workspace_reuse_flag, uint32_t index, int64_t stream_id,
                                           MemoryBlock *mem_block, int64_t memory_type) {
                                           MemoryBlock *mem_block, uint64_t memory_type) {
  bool reuse_mem_flag =
      ((workspace_reuse_flag.size() > index) && (workspace_reuse_flag[index] == false)) ? false : true;
  if (reuse_mem_flag) {
@@ -1992,24 +1993,29 @@ void BlockMemAssigner::ReuseBlocksByLifeTime(size_t range_size) {
  }
 }

 void AddBlockMemOffset(size_t &mem_offset, size_t &p2p_mem_offset, MemoryBlock &block) {
  if (block.memory_type_ == RT_MEMORY_HBM) {
    if (block.first_continuous_block_) {
      mem_offset += MEM_ALIGN_SIZE;
    }
    block.Resize();
    block.SetHeadOffset(mem_offset);
    mem_offset += block.Size();
    block.SetTailOffset(mem_offset - 1);
  } else if (block.memory_type_ == RT_MEMORY_P2P_DDR) {
    if (block.first_continuous_block_) {
      p2p_mem_offset += MEM_ALIGN_SIZE;
 void AddBlockMemOffset(std::map<uint64_t, size_t> &mem_offsets, MemoryBlock &block) {
  auto it = mem_offsets.find(block.memory_type_);
  if (it == mem_offsets.end()) {
    auto result = mem_offsets.insert(std::pair<int64_t, size_t>(block.memory_type_, 0));
    // Insert failure is unlikely
    if (!result.second) {
      return;
    }
    block.Resize();
    block.SetHeadOffset(p2p_mem_offset);
    p2p_mem_offset += block.Size();
    block.SetTailOffset(p2p_mem_offset - 1);
    it = result.first;
  }

  if (it == mem_offsets.end()) {
    return;
  }

  auto &mem_offset = it->second;
  if (block.first_continuous_block_) {
    mem_offset += MEM_ALIGN_SIZE;
  }
  block.Resize();
  block.SetHeadOffset(mem_offset);
  mem_offset += block.Size();
  block.SetTailOffset(mem_offset - 1);
 }

 bool DynamicBatchBlockReuse(MemoryBlock &block) {
@@ -2036,27 +2042,27 @@ void BlockMemAssigner::ResizeDynamicBatchBlocks() {
    }
  }

  size_t max_mem_offset = mem_offset_;
  size_t max_p2p_mem_offset = p2p_mem_offset_;
  std::map<uint64_t, size_t> max_mem_offsets = mem_offsets_;
  for (auto &batch_blocks : dynamic_batch_blocks) {
    size_t mem_offset = mem_offset_;
    size_t p2p_mem_offset = p2p_mem_offset_;
    std::map<uint64_t, size_t> mem_offsets = mem_offsets_;
    for (auto block : batch_blocks.second) {
      if (block == nullptr || block->deleted_block_ || block->is_zero_copy_) {
        continue;
      }
      AddBlockMemOffset(mem_offset, p2p_mem_offset, *block);
      AddBlockMemOffset(mem_offsets, *block);
    }
    if (mem_offset > max_mem_offset) {
      max_mem_offset = mem_offset;
    }
    if (p2p_mem_offset > max_p2p_mem_offset) {
      max_p2p_mem_offset = p2p_mem_offset;

    for (auto &it : mem_offsets) {
      auto itmax = max_mem_offsets.find(it.first);
      if (itmax == max_mem_offsets.end()) {
        max_mem_offsets[it.first] = it.second;
      } else if (it.second > itmax->second) {
        itmax->second = it.second;
      }
      GELOGI("Batch:%s memory type:%ld offset:%zu", batch_blocks.first.c_str(), it.first, it.second);
    }
    GELOGI("Batch[%s] offset[%zu] p2p_offset[%zu]", batch_blocks.first.c_str(), mem_offset, p2p_mem_offset);
  }
  mem_offset_ = max_mem_offset;
  p2p_mem_offset_ = max_p2p_mem_offset;
  mem_offsets_ = max_mem_offsets;
 }

 ///
@@ -2074,11 +2080,13 @@ void BlockMemAssigner::ResizeMemoryBlocks() {
      continue;
    }

    AddBlockMemOffset(mem_offset_, p2p_mem_offset_, *memory_block);
    AddBlockMemOffset(mem_offsets_, *memory_block);
  }
  ResizeDynamicBatchBlocks();
  GELOGI("mem_offset_ exclude zero_copy_memory is %zu, p2p_mem_offset_ exclude zero_copy_memory is %zu,"
         "theory_min_memory_size %zu", mem_offset_, p2p_mem_offset_, theory_min_memory_size_);
  for (auto it : mem_offsets_) {
    GELOGI("Memory type:%ld mem_offset exclude zero_copy_memory:%zu, theory_min_memory_size:%zu", it.first, it.second,
           theory_min_memory_size_);
  }
 }

 ///
@@ -2217,7 +2225,8 @@ bool BlockMemAssigner::CheckIsZeroMemNodeType(const string &node_type) const {
         (node_type == CONSTANTOP) || (node_type == HVDWAIT);
 }

 bool BlockMemAssigner::GetWorkSpaceMemoryType(const NodePtr &node, size_t index, int64_t &memory_type) {
 bool BlockMemAssigner::GetWorkSpaceMemoryType(const NodePtr &node, size_t index, uint64_t &memory_type,
                                              vector<bool> &workspace_reuse_flag) {
  memory_type = RT_MEMORY_HBM;
  vector<int64_t> workspace_memory_type;
  auto op_desc = node->GetOpDesc();
@@ -2233,6 +2242,20 @@ bool BlockMemAssigner::GetWorkSpaceMemoryType(const NodePtr &node, size_t index,
    return false;
  }
  memory_type = has_workspace_mem_type_attr ? workspace_memory_type[index] : RT_MEMORY_HBM;

  vector<int32_t> workspace_no_reuse_scope;
  bool has_workspace_no_reuse_scope =
    ge::AttrUtils::GetListInt(op_desc, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope);
  if (has_workspace_no_reuse_scope && (index < workspace_no_reuse_scope.size())
      && (workspace_no_reuse_scope[index] == kSessionNoReuse)) {
    memory_type |= kSessionScopeMemory;
    if (workspace_reuse_flag.empty()) {
      workspace_reuse_flag.assign(workspace_no_reuse_scope.size(), true);
    }
    // set to no reuse
    workspace_reuse_flag[index] = false;
    GELOGI("%s's workspace is session scope no reuse, memory type:%lu.", node->GetName().c_str(), memory_type);
  }
  return true;
 }
 }  // namespace ge
--- a/ge/graph/build/memory/block_mem_assigner.h
+++ b/ge/graph/build/memory/block_mem_assigner.h
@@ -34,6 +34,10 @@
 namespace ge {
 const size_t kMaxLifeTime = 0xffffffff;
 const int32_t kInvalidThreadScopeId = -1;
 const uint64_t kSessionScopeMemory = 0x100000000;
 const uint64_t kMemoryTypeMask = 0xffffffff;

 enum MemoryNoReuseScope { kReuse, kSessionNoReuse, kGraphNoReuse };

 using DependStreamLife = std::map<int64_t, std::map<int64_t, size_t>>;

@@ -224,9 +228,7 @@ class BlockMemAssigner : public MemAssigner {

  Status Assign() override;

  size_t GetMemOffset() const { return mem_offset_; }

  size_t GetP2PMemOffset() const { return p2p_mem_offset_; }
  const std::map<uint64_t, size_t> &GetMemOffsets() const { return mem_offsets_; }

  int64_t GetAtomicAddrCleanId() const { return atomic_addr_clean_id_; }

@@ -329,14 +331,10 @@ class BlockMemAssigner : public MemAssigner {
  ///
  void UpdateOpTensorMemType(std::list<NodeIndexIO> node_index_io_list, int64_t memory_type);

  size_t mem_offset_;
  size_t p2p_mem_offset_;

  std::map<uint64_t, size_t> mem_offsets_;
  ge::ComputeGraphPtr compute_graph_;

  std::vector<MemoryBlock *> memory_blocks_;
  std::vector<MemoryBlock *> blocks_store_;

  std::vector<NodeTypeIndex> zero_memory_list_;

  // ref mapping
@@ -380,7 +378,7 @@ class BlockMemAssigner : public MemAssigner {
  ///
  MemoryBlock *ApplyMemory(size_t block_size, size_t real_size, size_t no_align_size, OpMemoryType mem_type,
                           const ge::NodePtr &n, uint32_t out_index, const std::vector<bool> &workspace_reuse_flag,
                           const bool is_op_reuse_mem, const bool continuous, int64_t memory_type);
                           const bool is_op_reuse_mem, const bool continuous, uint64_t memory_type);

  ///
  /// @ingroup GE
@@ -394,7 +392,7 @@ class BlockMemAssigner : public MemAssigner {
  /// @author
  ///
  void CheckWorkspaceReuse(const vector<bool> &workspace_reuse_flag, uint32_t index, int64_t stream_id,
                           MemoryBlock *mem_block, int64_t memory_type);
                           MemoryBlock *mem_block, uint64_t memory_type);

  ///
  /// @ingroup GE
@@ -457,7 +455,8 @@ class BlockMemAssigner : public MemAssigner {

  bool IsContinuousOutput(const NodePtr &n);

  bool GetWorkSpaceMemoryType(const NodePtr &node, size_t index, int64_t &memory_type);
  bool GetWorkSpaceMemoryType(const NodePtr &node, size_t index, uint64_t &memory_type,
                              vector<bool> &workspace_reuse_flag);

  void ContinuousOutRefCheck(bool &isAllOutputRef, bool &isOutputHasRef, const NodePtr &n);

--- a/ge/graph/build/memory/graph_mem_assigner.cc
+++ b/ge/graph/build/memory/graph_mem_assigner.cc
@@ -107,11 +107,22 @@ Status GraphMemoryAssigner::AssignMemory() {
           compute_graph_->GetGraphID(), compute_graph_->GetName().c_str());
    return ge::FAILED;
  }
  MemoryOffset memory_offset(RT_MEMORY_HBM, mem_assigner->GetMemOffset());
  memory_offset_.emplace(RT_MEMORY_HBM, memory_offset);

  if (mem_assigner->GetP2PMemOffset() >= 0) {
    MemoryOffset p2p_memory_offset(RT_MEMORY_P2P_DDR, mem_assigner->GetP2PMemOffset());
  for (auto pair : mem_assigner->GetMemOffsets()) {
    MemoryOffset offset(pair.first, pair.second);
    memory_offset_.emplace(pair.first, offset);
  }

  // base memtype offset must be exist
  auto it = mem_assigner->GetMemOffsets().find(RT_MEMORY_HBM);
  if (it == mem_assigner->GetMemOffsets().end()) {
    MemoryOffset memory_offset(RT_MEMORY_HBM, 0);
    memory_offset_.emplace(RT_MEMORY_HBM, memory_offset);
  }

  it = mem_assigner->GetMemOffsets().find(RT_MEMORY_P2P_DDR);
  if (it == mem_assigner->GetMemOffsets().end()) {
    MemoryOffset p2p_memory_offset(RT_MEMORY_P2P_DDR, 0);
    memory_offset_.emplace(RT_MEMORY_P2P_DDR, p2p_memory_offset);
  }

@@ -224,7 +235,7 @@ ge::Status CalculateTensorRealSizeAndOutSize(const ge::ConstGeTensorDescPtr &out
  return SUCCESS;
 }

 Status GraphMemoryAssigner::ReAssignMemory(bool is_loop_graph, map<int64_t, size_t> &mem_type_to_offset) {
 Status GraphMemoryAssigner::ReAssignMemory(bool is_loop_graph, map<uint64_t, size_t> &mem_type_to_offset) {
  if (memory_offset_.empty()) {
    REPORT_INNER_ERROR("E19999", "InnerData memory_offset_ empty, not expected, graph_id:%u, graph_name:%s",
                       compute_graph_->GetGraphID(), compute_graph_->GetName().c_str());
@@ -264,7 +275,7 @@ Status GraphMemoryAssigner::ReAssignMemory(bool is_loop_graph, map<int64_t, size
  return SUCCESS;
 }

 Status GraphMemoryAssigner::AssignZeroCopyMemory(map<int64_t, size_t> &mem_offset, size_t &zero_mem_copy_size) {
 Status GraphMemoryAssigner::AssignZeroCopyMemory(map<uint64_t, size_t> &mem_offset, size_t &zero_mem_copy_size) {
  BlockMemAssignerPtr priority_assigner = std::move(mem_assigner_->GetPriorityAssinger());
  if (priority_assigner == nullptr) {
    REPORT_INNER_ERROR("E19999", "InnerData priority_assigner nullptr, not expected, graph_id:%u, graph_name:%s",
@@ -1398,6 +1409,9 @@ ge::Status GraphMemoryAssigner::SetInputOffset() {
           "graph_id:%u, graph_name:%s", compute_graph_->GetGraphID(), compute_graph_->GetName().c_str());
  }
  for (auto pair : memory_offset_) {
    if ((pair.first != RT_MEMORY_HBM) && (pair.second.mem_offset_ == 0)) {
      continue;
    }
    GEEVENT("[IMAS]AfterAssignMemory : %s memoffset[%zu], memtype[%ld]", compute_graph_->GetName().c_str(),
            pair.second.mem_offset_, pair.first);
  }
--- a/ge/graph/build/memory/graph_mem_assigner.h
+++ b/ge/graph/build/memory/graph_mem_assigner.h
@@ -103,9 +103,9 @@ class GraphMemoryAssigner {

  ge::Status AssignMemory2HasRefAttrNode();

  ge::Status ReAssignMemory(bool is_loop_graph, map<int64_t, size_t> &mem_type_to_offset);
  ge::Status ReAssignMemory(bool is_loop_graph, map<uint64_t, size_t> &mem_type_to_offset);

  ge::Status AssignZeroCopyMemory(map<int64_t, size_t> &mem_offset, size_t &zero_mem_copy_size);
  ge::Status AssignZeroCopyMemory(map<uint64_t, size_t> &mem_offset, size_t &zero_mem_copy_size);

  ge::Status SetInputOffset();

--- a/ge/graph/build/memory/hybrid_mem_assigner.cc
+++ b/ge/graph/build/memory/hybrid_mem_assigner.cc
@@ -23,7 +23,7 @@

 namespace ge {
 HybridMemAssigner::HybridMemAssigner(ge::ComputeGraphPtr compute_graph)
    : mem_offset_(0), p2p_mem_offset_(0), compute_graph_(std::move(compute_graph)), priority_assigner_(nullptr) {}
    : compute_graph_(std::move(compute_graph)), priority_assigner_(nullptr) {}

 Status HybridMemAssigner::AssignMemory(std::unique_ptr<BlockMemAssigner> &block_assigner, size_t &mem_size) {
  vector<int64_t> ranges;
@@ -36,7 +36,10 @@ Status HybridMemAssigner::AssignMemory(std::unique_ptr<BlockMemAssigner> &block_

  block_assigner->AssignMemoryWithReuse(ranges);

  mem_size = block_assigner->GetMemOffset();
  // total size
  for (auto it : block_assigner->GetMemOffsets()) {
    mem_size += it.second;
  }
  return SUCCESS;
 }

@@ -73,8 +76,7 @@ Status HybridMemAssigner::Assign() {
  }

  priority_assigner->SetOpMemOffset(false);
  mem_offset_ = priority_assigner->GetMemOffset();
  p2p_mem_offset_ = priority_assigner->GetP2PMemOffset();
  mem_offsets_ = priority_assigner->GetMemOffsets();
  priority_assigner_ = std::move(priority_assigner);

  return SUCCESS;
--- a/ge/graph/build/memory/hybrid_mem_assigner.h
+++ b/ge/graph/build/memory/hybrid_mem_assigner.h
@@ -42,16 +42,14 @@ class HybridMemAssigner : public MemAssigner {

  Status Assign() override;

  size_t GetMemOffset() const { return mem_offset_; }
  size_t GetP2PMemOffset() const { return p2p_mem_offset_; }
  const std::map<uint64_t, size_t> &GetMemOffsets() const { return mem_offsets_; }

  BlockMemAssignerPtr GetPriorityAssinger() const { return priority_assigner_; }

 private:
  Status AssignMemory(std::unique_ptr<BlockMemAssigner> &block_assigner, size_t &mem_size);

  size_t mem_offset_;
  size_t p2p_mem_offset_;
  std::map<uint64_t, size_t> mem_offsets_;

  ge::ComputeGraphPtr compute_graph_;

--- a/ge/graph/build/memory/memory_assigner.cc
+++ b/ge/graph/build/memory/memory_assigner.cc
@@ -20,7 +20,7 @@
 #include "graph/build/memory/graph_mem_assigner.h"

 namespace ge {
 Status MemoryAssigner::AssignMemory(bool is_loop_graph, map<int64_t, size_t> &mem_offset, size_t &zero_copy_mem_size) {
 Status MemoryAssigner::AssignMemory(bool is_loop_graph, map<uint64_t, size_t> &mem_offset, size_t &zero_copy_mem_size) {
  GraphMemoryAssigner graph_mem_assigner(compute_graph_);

  if (graph_mem_assigner.AssignMemory() != ge::SUCCESS) {
--- a/ge/graph/build/model_builder.cc
+++ b/ge/graph/build/model_builder.cc
@@ -47,6 +47,7 @@
 #include "omg/version.h"
 #include "register/op_registry.h"
 #include "graph/passes/set_input_output_offset_pass.h"
 #include "graph/build/memory/block_mem_assigner.h"

 using std::map;
 using std::set;
@@ -398,9 +399,21 @@ Status ModelBuilder::BuildModelDef(ge::Model &model) {
                   REPORT_INNER_ERROR("E19999", "Set Attr:%s in model failed", ATTR_MODEL_MEMORY_SIZE.c_str());
                   GELOGE(FAILED, "[Set][Attr] %s in model failed", ATTR_MODEL_MEMORY_SIZE.c_str());
                   return FAILED);
  auto mem_type_session_scope = (kSessionScopeMemory | RT_MEMORY_HBM);
  size_t session_scope_mem_offset = 0;
  auto it = mem_type_to_mem_offset_.find(mem_type_session_scope);
  if (it != mem_type_to_mem_offset_.end()) {
    session_scope_mem_offset = it->second;
  }
  if (mem_type_to_mem_offset_.find(RT_MEMORY_P2P_DDR) != mem_type_to_mem_offset_.end()) {
    p2p_mem_offset_ = mem_type_to_mem_offset_[RT_MEMORY_P2P_DDR];
  }
  GE_CHK_BOOL_EXEC(ge::AttrUtils::SetInt(&model, ATTR_MODEL_SESSION_SCOPE_MEMORY_SIZE, session_scope_mem_offset),
                   REPORT_INNER_ERROR("E19999", "Set Attr:%s in model failed",
                                      ATTR_MODEL_SESSION_SCOPE_MEMORY_SIZE.c_str());
  GELOGE(FAILED, "SetInt of ATTR_NAME_SESSION_SCOPE_MEMORY_SIZE failed.");
  return FAILED);

  GE_CHK_BOOL_EXEC(ge::AttrUtils::SetInt(&model, ATTR_MODEL_P2P_MEMORY_SIZE, p2p_mem_offset_),
                   REPORT_INNER_ERROR("E19999", "Set Attr:%s in model failed", ATTR_MODEL_P2P_MEMORY_SIZE.c_str());
                   GELOGE(FAILED, "[Set][Attr] %s in model failed", ATTR_MODEL_P2P_MEMORY_SIZE.c_str());
@@ -434,8 +447,8 @@ Status ModelBuilder::BuildModelDef(ge::Model &model) {
                   REPORT_INNER_ERROR("E19999", "Set Attr:%s in model failed", ATTR_MODEL_OUT_NODES_NAME.c_str());
                   GELOGE(FAILED, "[Set][Str] %s in model failed.", ATTR_MODEL_OUT_NODES_NAME.c_str());
                   return FAILED);
  GELOGI("For model, max_mem_offset_: %zu, p2p_mem_size: %zu, zero_copy_mem_size_: %zu", max_mem_offset_,
         p2p_mem_offset_, zero_copy_mem_size_);
  GELOGI("For model, max_mem_offset: %zu, p2p_mem_size: %zu, zero_copy_mem_size: %zu, session_scope_mem_size: %zu",
         max_mem_offset_, p2p_mem_offset_, zero_copy_mem_size_, session_scope_mem_offset);
  string fp_ceiling_mode;
  if (ge::GetContext().GetOption("ge.fpCeilingMode", fp_ceiling_mode) == SUCCESS) {
    if (!ge::AttrUtils::SetStr(&model, ATTR_FP_CEILING_MODE, fp_ceiling_mode)) {
--- a/ge/graph/build/model_builder.h
+++ b/ge/graph/build/model_builder.h
@@ -93,7 +93,7 @@ class ModelBuilder {

  uint64_t session_id_;

  map<int64_t, size_t> mem_type_to_mem_offset_;
  map<uint64_t, size_t> mem_type_to_mem_offset_;

  size_t weight_offset_;

--- a/ge/graph/load/model_manager/davinci_model.cc
+++ b/ge/graph/load/model_manager/davinci_model.cc
@@ -40,7 +40,7 @@
 #include "graph/load/model_manager/cpu_queue_schedule.h"
 #include "graph/load/model_manager/model_manager.h"
 #include "graph/load/model_manager/tbe_handle_store.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "graph/manager/graph_var_manager.h"
 #include "graph/manager/trans_var_data_utils.h"
 #include "graph/manager/util/debug.h"
@@ -60,6 +60,8 @@
 #include "graph/common/local_context.h"
 #include "common/formats/utils/formats_trans_utils.h"
 #include "graph/common/omg_util.h"
 #include "graph/build/memory/block_mem_assigner.h"
 #include "graph/manager/session_scope_mem_allocator.h"

 // create std::thread, catch exceptions using try/catch
 #define CREATE_STD_THREAD(thread_id, func, args)                                                  \
@@ -168,7 +170,6 @@ DavinciModel::DavinciModel(int32_t priority, const std::shared_ptr<ModelListener
      mem_base_(nullptr),
      is_inner_mem_base_(false),
      is_inner_weight_base_(false),
      is_inner_p2p_mem_base_(false),
      data_inputer_(nullptr),
      load_begin_time_(0),
      load_end_time_(0),
@@ -236,7 +237,7 @@ DavinciModel::~DavinciModel() {

      FreeFeatureMapMem();

      FreeP2PMem();
      FreeExMem();

      OpDebugUnRegister();

@@ -389,7 +390,6 @@ Status DavinciModel::InitFeatureMapAndP2PMem(void *dev_ptr, size_t mem_size) {
  is_feature_map_mem_has_inited_ = true;

  std::size_t data_size = TotalMemSize();
  std::size_t p2p_data_size = P2PMemInfos().at(RT_MEMORY_P2P_DDR).memory_size;

  if ((dev_ptr != nullptr) && (mem_size < TotalMemSize())) {
    REPORT_INNER_ERROR("E19999", "Param dev_ptr is nullptr or mem_size:%zu < ge_model.mem_size:%zu, "
@@ -400,7 +400,6 @@ Status DavinciModel::InitFeatureMapAndP2PMem(void *dev_ptr, size_t mem_size) {
  }

  mem_base_ = static_cast<uint8_t *>(dev_ptr);
  p2p_mem_base_ = static_cast<uint8_t *>(dev_ptr);
  is_inner_mem_base_ = false;

  if (TotalMemSize() && mem_base_ == nullptr) {
@@ -422,24 +421,13 @@ Status DavinciModel::InitFeatureMapAndP2PMem(void *dev_ptr, size_t mem_size) {
    is_inner_mem_base_ = true;
  }

  if (p2p_data_size != 0) {
    p2p_mem_base_ = MallocP2PMem(p2p_data_size);
    if (p2p_mem_base_ == nullptr) {
      REPORT_CALL_ERROR("E19999", "MallocFeatureMapMem fail, p2p_data_size:%zu, model_id:%u, check invalid",
                        p2p_data_size, model_id_);
      GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "[Alloc][Memory] for p2p failed, size:%zu, model_id:%u",
             p2p_data_size, model_id_);
      return ACL_ERROR_GE_MEMORY_ALLOCATION;
    }
    GELOGI("InitFeatureMapAndP2PMem graph_%u MallocMemory type[F] memaddr[%p] mem_size[%zu]", runtime_param_.graph_id,
           p2p_mem_base_, p2p_data_size);
    is_inner_p2p_mem_base_ = true;
  if (!runtime_param_.memory_infos.empty()) {
    GE_CHK_STATUS_RET(MallocExMem(), "MallocExMem failed.");
  }

  GE_CHK_STATUS_RET(InitVariableMem(), "[Init][VariableMemory] failed, model_id:%u", model_id_);
  runtime_param_.mem_base = mem_base_;
  runtime_param_.weight_base = weights_mem_base_;
  runtime_param_.memory_infos[RT_MEMORY_P2P_DDR].memory_base = p2p_mem_base_;
  return SUCCESS;
 }

@@ -465,7 +453,6 @@ Status DavinciModel::InitVariableMem() {
 void DavinciModel::InitRuntimeParams() {
  int64_t value = 0;
  bool ret;
  MemInfo p2p_mem_info;
  ret = ge::AttrUtils::GetInt(ge_model_, ATTR_MODEL_MEMORY_SIZE, value);
  runtime_param_.mem_size = ret ? (uint64_t)value : 0;
  ret = ge::AttrUtils::GetInt(ge_model_, ATTR_MODEL_WEIGHT_SIZE, value);
@@ -490,16 +477,18 @@ void DavinciModel::InitRuntimeParams() {
  runtime_param_.var_size = ret ? (uint64_t)value : 0;
  session_id_ = runtime_param_.session_id;
  ret = ge::AttrUtils::GetInt(ge_model_, ATTR_MODEL_P2P_MEMORY_SIZE, value);
  p2p_mem_info.memory_size = ret ? (uint64_t)value : 0;
  MemInfo p2p_mem_info;
  p2p_mem_info.memory_size = static_cast<size_t>(ret ? value : 0);
  p2p_mem_info.memory_type = RT_MEMORY_P2P_DDR;
  p2p_mem_info.memory_key = "_p";
  runtime_param_.memory_infos[RT_MEMORY_P2P_DDR] = std::move(p2p_mem_info);

  GELOGI(
      "InitRuntimeParams(), session_id:%lu, stream_num:%u, event_num:%u, label_num:%u, "
      "logic_mem_base:0x%lx, logic_weight_base:0x%lx, logic_var_base:0x%lx, "
      "memory_size:%lu, weight_size:%lu, var_size:%lu",
      runtime_param_.session_id, runtime_param_.stream_num, runtime_param_.event_num, runtime_param_.label_num,
      runtime_param_.logic_mem_base, runtime_param_.logic_weight_base, runtime_param_.logic_var_base,
      runtime_param_.mem_size, runtime_param_.weight_size, runtime_param_.var_size);
  ret = ge::AttrUtils::GetInt(ge_model_, ATTR_MODEL_SESSION_SCOPE_MEMORY_SIZE, value);
  MemInfo session_scope_mem_info;
  session_scope_mem_info.memory_size = static_cast<size_t>(ret ? value : 0);
  runtime_param_.memory_infos[kSessionScopeMemory | RT_MEMORY_HBM] = std::move(session_scope_mem_info);

  GELOGI("InitRuntimeParams(), %s.", runtime_param_.ToString().c_str());
 }

 void DavinciModel::CheckHasHcomOp(const ComputeGraphPtr &compute_graph) {
@@ -4089,14 +4078,15 @@ Status DavinciModel::InitEntryTask() {
 uint8_t *DavinciModel::MallocFeatureMapMem(size_t data_size) {
  uint8_t *mem_base = nullptr;
  const string purpose("feature map,used for op input and output.");
  char ge_static_mem_env[MMPA_MAX_PATH] = { 0x00 };
  char ge_static_mem_env[MMPA_MAX_PATH] = {0x00};
  INT32 res = mmGetEnv(kEnvGeuseStaticMemory, ge_static_mem_env, MMPA_MAX_PATH);
  if (res == EN_OK) {
    data_size = static_cast<size_t>(VarManager::Instance(session_id_)->GetGraphMemoryMaxSize());
    string memory_key = std::to_string(0) + "_f";
    mem_base = MemManager::Instance(RT_MEMORY_HBM)->MallocMemory(purpose, memory_key, data_size, GetDeviceId());
    mem_base =
      MemManager::Instance().MemInstance(RT_MEMORY_HBM).MallocMemory(purpose, memory_key, data_size, GetDeviceId());
  } else {
    mem_base = MemManager::Instance(RT_MEMORY_HBM)->MallocMemory(purpose, data_size, GetDeviceId());
    mem_base = MemManager::Instance().MemInstance(RT_MEMORY_HBM).MallocMemory(purpose, data_size, GetDeviceId());
  }

  if (mem_base != nullptr) {
@@ -4105,83 +4095,119 @@ uint8_t *DavinciModel::MallocFeatureMapMem(size_t data_size) {
  return mem_base;
 }

 uint8_t *DavinciModel::MallocP2PMem(size_t p2p_data_size) {
  uint8_t *p2p_mem_base = nullptr;
  const string purpose("p2p memory, used for some op related to hcom");
  if (std::getenv(kEnvGeuseStaticMemory) != nullptr) {
    string p2p_memory_key = std::to_string(0) + "_p";
    p2p_mem_base =
        MemManager::Instance(RT_MEMORY_P2P_DDR)->MallocMemory(purpose, p2p_memory_key, p2p_data_size, GetDeviceId());
  } else {
    p2p_mem_base = MemManager::Instance(RT_MEMORY_P2P_DDR)->MallocMemory(purpose, p2p_data_size, GetDeviceId());
 Status DavinciModel::MallocExMem() {
  char ge_static_mem_env[MMPA_MAX_PATH] = {0x00};
  INT32 res_static_memory = mmGetEnv(kEnvGeuseStaticMemory, ge_static_mem_env, MMPA_MAX_PATH);
  for (auto it : runtime_param_.memory_infos) {
    auto mem_size = it.second.memory_size;
    if (mem_size == 0) {
      continue;
    }
    bool sessoion_scope = ((kSessionScopeMemory & it.first) == kSessionScopeMemory);
    auto mem_type = it.first & kMemoryTypeMask;
    uint8_t *mem_base = nullptr;
    const string purpose("p2p memory, used for some op related to hcom or session scope memory");
    if (sessoion_scope) {
      mem_base = MemManager::Instance().SessionScopeMemInstance(mem_type).Malloc(mem_size, runtime_param_.session_id);
    } else if (res_static_memory == EN_OK) {
      string memory_key = std::to_string(0) + it.second.memory_key;
      mem_base =
        MemManager::Instance().MemInstance(mem_type).MallocMemory(purpose, memory_key, mem_size, GetDeviceId());
    } else {
      mem_base = MemManager::Instance().MemInstance(mem_type).MallocMemory(purpose, mem_size, GetDeviceId());
    }

    if (mem_base == nullptr) {
      REPORT_CALL_ERROR("E19999", "MallocExMem fail, type:%ld size:%zu, model_id:%u, check invalid",
                        mem_type, mem_size, model_id_);
      GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Alloc ex memory failed, type:%ld size: %zu", mem_type, mem_size);
      return ACL_ERROR_GE_MEMORY_ALLOCATION;
    }
    it.second.memory_base = mem_base;
    GELOGI("InitFeatureMapAndP2PMem graph_%u MallocMemory type[F] mem_type[%ld] mem_addr[%p] mem_size[%zu]",
           runtime_param_.graph_id, mem_type, mem_base, mem_size);
  }
  return p2p_mem_base;
  return SUCCESS;
 }

 uint8_t *DavinciModel::MallocWeightsMem(size_t weights_size) {
  uint8_t *weights_mem_base = nullptr;
  const string purpose("weights memory in inference network.");
  char ge_static_mem_env[MMPA_MAX_PATH] = { 0x00 };
  char ge_static_mem_env[MMPA_MAX_PATH] = {0x00};
  INT32 res = mmGetEnv(kEnvGeuseStaticMemory, ge_static_mem_env, MMPA_MAX_PATH);
  if (res == EN_OK) {
    string weight_memory_key = std::to_string(0) + "_w";
    weights_mem_base =
        MemManager::Instance(RT_MEMORY_HBM)->MallocMemory(purpose, weight_memory_key, weights_size, GetDeviceId());
    weights_mem_base = MemManager::Instance()
                         .MemInstance(RT_MEMORY_HBM)
                         .MallocMemory(purpose, weight_memory_key, weights_size, GetDeviceId());
  } else {
    weights_mem_base = MemManager::Instance(RT_MEMORY_HBM)->MallocMemory(purpose, weights_size, GetDeviceId());
    weights_mem_base =
      MemManager::Instance().MemInstance(RT_MEMORY_HBM).MallocMemory(purpose, weights_size, GetDeviceId());
  }
  return weights_mem_base;
 }

 void DavinciModel::FreeFeatureMapMem() {
  char ge_static_mem_env[MMPA_MAX_PATH] = { 0x00 };
  char ge_static_mem_env[MMPA_MAX_PATH] = {0x00};
  INT32 res = mmGetEnv(kEnvGeuseStaticMemory, ge_static_mem_env, MMPA_MAX_PATH);
  if (res == EN_OK && is_inner_mem_base_) {
    string weight_memory_key = std::to_string(0) + "_f";
    if (MemManager::Instance(RT_MEMORY_HBM)->GetMemoryAddr(weight_memory_key) != nullptr) {
      GE_CHK_STATUS(MemManager::Instance(RT_MEMORY_HBM)->FreeMemory(weight_memory_key, GetDeviceId()),
                    "[Free][Memory] failed, model_id:%u", model_id_);
    if (MemManager::Instance().MemInstance(RT_MEMORY_HBM).GetMemoryAddr(weight_memory_key) != nullptr) {
      GE_CHK_STATUS(MemManager::Instance().MemInstance(RT_MEMORY_HBM).FreeMemory(weight_memory_key, GetDeviceId()),
                    "failed to free weight memory");
    }
    mem_base_ = nullptr;
  } else {
    GE_IF_BOOL_EXEC(mem_base_ != nullptr && is_inner_mem_base_,
                    GE_CHK_STATUS(MemManager::Instance(RT_MEMORY_HBM)->FreeMemory(mem_base_, GetDeviceId()),
                                  "[Free][Memory] failed, model_id:%u", model_id_);
                    mem_base_ = nullptr);
    GE_IF_BOOL_EXEC(
      mem_base_ != nullptr && is_inner_mem_base_,
      GE_CHK_STATUS(MemManager::Instance().MemInstance(RT_MEMORY_HBM).FreeMemory(mem_base_, GetDeviceId()),
                    "failed to free feature_map memory");
      mem_base_ = nullptr);
  }
 }

 void DavinciModel::FreeP2PMem() {
  if (std::getenv(kEnvGeuseStaticMemory) != nullptr) {
    std::string p2p_memory_key = std::to_string(0) + "_p";
    if (MemManager::Instance(RT_MEMORY_P2P_DDR)->GetMemoryAddr(p2p_memory_key) != nullptr) {
      GE_CHK_STATUS(MemManager::Instance(RT_MEMORY_P2P_DDR)->FreeMemory(p2p_memory_key, GetDeviceId()),
                    "[Free][Memory] failed, model_id:%u", model_id_);
 void DavinciModel::FreeExMem() {
  char ge_static_mem_env[MMPA_MAX_PATH] = {0x00};
  INT32 res_static_memory = mmGetEnv(kEnvGeuseStaticMemory, ge_static_mem_env, MMPA_MAX_PATH);
  for (auto it : runtime_param_.memory_infos) {
    // free when session destory
    if ((kSessionScopeMemory & it.first) == kSessionScopeMemory) {
      continue;
    }
    auto mem_type = it.first & kMemoryTypeMask;
    if (res_static_memory == EN_OK) {
      std::string memory_key = std::to_string(0) + it.second.memory_key;
      if (MemManager::Instance().MemInstance(mem_type).GetMemoryAddr(memory_key) != nullptr) {
        GE_CHK_STATUS(MemManager::Instance().MemInstance(mem_type).FreeMemory(memory_key, GetDeviceId()),
                      "failed to free memory");
      }
      it.second.memory_base = nullptr;
    } else {
      GE_IF_BOOL_EXEC(
        it.second.memory_base != nullptr,
        GE_CHK_STATUS(MemManager::Instance().MemInstance(mem_type).FreeMemory(it.second.memory_base, GetDeviceId()),
                      "failed to free memory");
        it.second.memory_base = nullptr);
    }
    p2p_mem_base_ = nullptr;
  } else {
    GE_IF_BOOL_EXEC(p2p_mem_base_ != nullptr && is_inner_mem_base_,
                    GE_CHK_STATUS(MemManager::Instance(RT_MEMORY_P2P_DDR)->FreeMemory(p2p_mem_base_, GetDeviceId()),
                                  "[Free][Memory] failed, model_id:%u", model_id_);
                    p2p_mem_base_ = nullptr);
  }
 }

 void DavinciModel::FreeWeightsMem() {
  char ge_static_mem_env[MMPA_MAX_PATH] = { 0x00 };
  char ge_static_mem_env[MMPA_MAX_PATH] = {0x00};
  INT32 res = mmGetEnv(kEnvGeuseStaticMemory, ge_static_mem_env, MMPA_MAX_PATH);
  if (res == EN_OK) {
    string memory_key = std::to_string(0) + "_w";
    if (MemManager::Instance(RT_MEMORY_HBM)->GetMemoryAddr(memory_key) != nullptr) {
      GE_CHK_STATUS(MemManager::Instance(RT_MEMORY_HBM)->FreeMemory(memory_key, GetDeviceId()),
                    "[Free][Memory] failed, model_id:%u", model_id_);
    if (MemManager::Instance().MemInstance(RT_MEMORY_HBM).GetMemoryAddr(memory_key) != nullptr) {
      GE_CHK_STATUS(MemManager::Instance().MemInstance(RT_MEMORY_HBM).FreeMemory(memory_key, GetDeviceId()),
                    "failed to free feature_map memory");
    }
    weights_mem_base_ = nullptr;
  } else {
    GE_IF_BOOL_EXEC(weights_mem_base_ != nullptr && weights_mem_base_ != mem_base_ && is_inner_weight_base_,
                    GE_CHK_STATUS(MemManager::Instance(RT_MEMORY_HBM)->FreeMemory(weights_mem_base_, GetDeviceId()),
                                  "[Free][Memory] failed, model_id:%u", model_id_);
                    weights_mem_base_ = nullptr);
    GE_IF_BOOL_EXEC(
      weights_mem_base_ != nullptr && weights_mem_base_ != mem_base_ && is_inner_weight_base_,
      GE_CHK_STATUS(MemManager::Instance().MemInstance(RT_MEMORY_HBM).FreeMemory(weights_mem_base_, GetDeviceId()),
                    "failed to free weight memory");
      weights_mem_base_ = nullptr);
  }
 }

--- a/ge/graph/load/model_manager/davinci_model.h
+++ b/ge/graph/load/model_manager/davinci_model.h
@@ -248,8 +248,6 @@ class DavinciModel {
  // get total mem size
  size_t TotalMemSize() const { return runtime_param_.mem_size; }

  const map<uint32_t, MemInfo> &P2PMemInfos() const { return runtime_param_.memory_infos; }

  // model name
  string Name() const { return name_; }

@@ -586,10 +584,8 @@ class DavinciModel {
  // memory address of model
  uintptr_t fixed_mem_base_;  // Initial of mem_base_, keep forever.
  uint8_t *mem_base_;
  uint8_t *p2p_mem_base_;
  bool is_inner_mem_base_;
  bool is_inner_weight_base_;
  bool is_inner_p2p_mem_base_;
  // input data manager
  DataInputer *data_inputer_;
  int64_t load_begin_time_;
@@ -668,13 +664,13 @@ class DavinciModel {

  uint8_t *MallocWeightsMem(size_t weights_size);

  uint8_t *MallocP2PMem(size_t p2p_data_size);
  Status MallocExMem();

  void FreeFeatureMapMem();

  void FreeWeightsMem();

  void FreeP2PMem();
  void FreeExMem();

  void ReleaseTask();

--- a/ge/graph/load/model_manager/model_utils.cc
+++ b/ge/graph/load/model_manager/model_utils.cc
@@ -21,6 +21,7 @@
 #include "graph/utils/tensor_utils.h"
 #include "graph/manager/graph_var_manager.h"
 #include "graph/types.h"
 #include "graph/build/memory/block_mem_assigner.h"

 #define VALIDATE_MEM_RANGE(OP, SIZE, OFFSET)                                                                 \
  do {                                                                                                       \
@@ -514,10 +515,16 @@ vector<void *> ModelUtils::GetWorkspaceDataAddrs(const RuntimeParam &model_param
  bool has_mem_type_attr = ge::AttrUtils::GetListInt(op_desc, TVM_ATTR_NAME_WORKSPACE_TYPE, v_memory_type);
  bool has_mem_type_workspace =
    ge::AttrUtils::GetListInt(op_desc, ATTR_NAME_WORKSPACE_TYPE_LIST, workspace_memory_type);

  vector<int32_t> workspace_no_reuse_scope;
  bool has_workspace_no_reuse_scope =
    ge::AttrUtils::GetListInt(op_desc, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope);

  for (size_t i = 0; i < v_workspace_bytes.size(); ++i) {
    // Temporary solution, the aicpu workspace of multiple images cannot be shared.
    if (has_workspace_reuse && i < workspace_reuse_flag.size() && !workspace_reuse_flag[i] &&
        !model_param.is_single_op) {
    bool aicpu_work_space = (has_workspace_reuse && i < workspace_reuse_flag.size() && !workspace_reuse_flag[i] &&
                             !model_param.is_single_op);
    if (aicpu_work_space) {
      void *mem_addr = model_param.aicpu_mem_mall->Acquire(v_workspace_offset[i], v_workspace_bytes[i]);
      v_workspace_data_addr.push_back(mem_addr);
      GELOGI(
@@ -548,7 +555,13 @@ vector<void *> ModelUtils::GetWorkspaceDataAddrs(const RuntimeParam &model_param
             model_param.graph_id, op_desc->GetName().c_str(), i, v_workspace_offset[i], v_workspace_bytes[i]);
    } else {
      VALIDATE_MEM_RANGE(op_desc, model_param.mem_size, v_workspace_offset[i]);
      uint8_t *mem_addr = model_param.mem_base + v_workspace_offset[i];
      uint8_t *mem_addr = nullptr;
      bool session_scope_memory = (has_workspace_no_reuse_scope) && (i < workspace_no_reuse_scope.size());
      if (session_scope_memory) {
        mem_addr = model_param.memory_infos.at(kSessionScopeMemory | RT_MEMORY_HBM).memory_base + v_workspace_offset[i];
      } else {
        mem_addr = model_param.mem_base + v_workspace_offset[i];
      }
      v_workspace_data_addr.push_back(mem_addr);
      GELOGI("[IMAS]GetWorkspaceDataAddrs graph_%u type[F] name[%s] workspace[%zu] offset[%ld] bytes[%ld] memaddr[%p]",
             model_param.graph_id, op_desc->GetName().c_str(), i, v_workspace_offset[i], v_workspace_bytes[i],
--- a/ge/graph/load/model_manager/task_info/task_info.h
+++ b/ge/graph/load/model_manager/task_info/task_info.h
@@ -18,6 +18,7 @@
 #define GE_GRAPH_LOAD_NEW_MODEL_MANAGER_TASK_INFO_TASK_INFO_H_

 #include <vector>
 #include <sstream>

 #include "cce/customize.h"
 #include "framework/common/taskdown_common.h"
@@ -28,9 +29,11 @@

 namespace ge {
 struct MemInfo {
  uint64_t memory_size = 0;
  size_t memory_size = 0;
  uint64_t logic_memory_base = 0;
  uint8_t *memory_base = nullptr;
  uint32_t memory_type = RT_MEMORY_HBM;
  std::string memory_key = "";
 };

 struct RuntimeParam {
@@ -40,6 +43,19 @@ struct RuntimeParam {
  }
  ~RuntimeParam() = default;

  std::string ToString() {
    std::stringstream ss;
    ss << "session_id:" << session_id << ", stream_num:" << stream_num << ", event_num:" << event_num
       << ", label_num:" << label_num << ", logic_mem_base:" << logic_mem_base
       << ", logic_weight_base:" << logic_weight_base << ", logic_var_base:" << logic_var_base
       << ", memory_size:" << mem_size << ", weight_size:" << weight_size << ", var_size:" << var_size
       << ", ex_memory_info:";
    for (auto it : memory_infos) {
      ss << "[memory_type:" << it.first << ", memory_size:" << it.second.memory_size << "]";
    }
    return ss.str();
  }

  uint64_t mem_size = 0;
  uint64_t logic_mem_base = 0;
  uint8_t *mem_base = nullptr;
@@ -49,7 +65,7 @@ struct RuntimeParam {
  uint64_t var_size = 0;
  uint64_t logic_var_base = 0;
  uint8_t *var_base = nullptr;
  std::map<uint32_t, MemInfo> memory_infos;
  std::map<uint64_t, MemInfo> memory_infos;
  uint32_t batch_num = 0;
  uint32_t stream_num = 0;
  uint32_t event_num = 0;
--- a/ge/graph/manager/graph_caching_allocator.cc
+++ b/ge/graph/manager/graph_caching_allocator.cc
@@ -21,7 +21,7 @@
 #include <utility>

 #include "framework/common/debug/ge_log.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"

 namespace ge {
 const size_t bin_ranges[kNumBins] = {kRoundBlockSize * kKByteSize,
@@ -117,7 +117,7 @@ Status CachingAllocator::Initialize(uint32_t device_id) {
    }
    free_block_bins_[i] = bin_ptr;
  }
  memory_allocator_ = MemManager::Instance(memory_type_);
  memory_allocator_ = &MemManager::Instance().MemInstance(memory_type_);
  if (memory_allocator_ == nullptr) {
    return ACL_ERROR_GE_INTERNAL_ERROR;
  }
--- a/ge/graph/manager/graph_caching_allocator.h
+++ b/ge/graph/manager/graph_caching_allocator.h
@@ -88,8 +88,8 @@ class CachingAllocator {
  ///
  /// @ingroup ge_graph
  /// @brief free memory
  /// @param [in] memory_ptr memory address ptr
  /// @param [in] device_id device id
  /// @param [out] memory_ptr memory address ptr
  /// @return Status result of function
  ///
  Status Free(uint8_t *memory_addr, uint32_t device_id = 0);
--- a/ge/graph/manager/graph_mem_allocator.cc
+++ b/ge/graph/manager/graph_mem_allocator.cc
@@ -17,11 +17,9 @@
 #include "graph/manager/graph_mem_allocator.h"

 #include <string>
 #include "graph/manager/graph_caching_allocator.h"
 #include "graph/manager/rdma_pool_allocator.h"
 #include "graph/manager/host_mem_allocator.h"

 namespace ge {
 void MemoryAllocator::Initialize(uint32_t device_id) {
 Status MemoryAllocator::Initialize(uint32_t device_id) {
  GELOGI("MemoryAllocator::Initialize");

  // when redo Initialize free memory
@@ -31,6 +29,7 @@ void MemoryAllocator::Initialize(uint32_t device_id) {
    }
  }
  memory_base_map_.clear();
  return SUCCESS;
 }

 void MemoryAllocator::Finalize(uint32_t device_id) {
@@ -152,113 +151,4 @@ uint8_t *MemoryAllocator::GetMemoryAddr(const string &memory_key, uint32_t devic

  return it->second.memory_addr_;
 }

 MemManager::MemManager() {}

 MemManager::~MemManager() { Finalize(); }

 MemManager &MemManager::Instance() {
  static MemManager mem_manager;
  return mem_manager;
 }

 MemoryAllocator *MemManager::Instance(rtMemType_t memory_type) { return Instance().GetMemoryAllocator(memory_type); }

 Status MemManager::Initialize(const std::vector<rtMemType_t> &memory_type) {
  std::lock_guard<std::recursive_mutex> lock(allocator_mutex_);
  MemoryAllocator *memory_allocator = nullptr;
  for (unsigned int index : memory_type) {
    auto it = memory_allocator_map_.find(index);
    if (it == memory_allocator_map_.end()) {
      memory_allocator = new (std::nothrow) MemoryAllocator(index);

      if (memory_allocator != nullptr) {
        memory_allocator_map_[index] = memory_allocator;
        GELOGI("Create MemoryAllocator memory type[%u] success.", index);
      } else {
        REPORT_CALL_ERROR("E19999", "New MemoryAllocator fail, index:%u", index);
        GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Alloc MemoryAllocator failed.");
      }
    } else {
      memory_allocator = it->second;
    }

    if (memory_allocator == nullptr) {
      GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Create MemoryAllocator failed.");
      return ACL_ERROR_GE_MEMORY_ALLOCATION;
    } else {
      memory_allocator->Initialize(0);
    }
  }

  auto ret = InitAllocator(memory_type, caching_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create CachingAllocator failed.");
    return ret;
  }

  ret = InitAllocator(memory_type, rdma_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create RdmaAllocator failed.");
    return ret;
  }

  ret = InitAllocator(memory_type, host_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create HostMemAllocator failed.");
    return ret;
  }
  return SUCCESS;
 }

 template <typename T>
 void FinalizeAllocatorMap(std::map<rtMemType_t, T *> &allocate_map) {
  for (auto &allocator : allocate_map) {
    if (allocator.second != nullptr) {
      allocator.second->Finalize();
      delete allocator.second;
      allocator.second = nullptr;
    }
  }
  allocate_map.clear();
 }

 void MemManager::Finalize() noexcept {
  GELOGI("Finalize.");
  std::lock_guard<std::recursive_mutex> lock(allocator_mutex_);
  // caching and rdma allocator use memory allocator, so finalize them first
  FinalizeAllocatorMap(caching_allocator_map_);
  FinalizeAllocatorMap(rdma_allocator_map_);
  FinalizeAllocatorMap(host_allocator_map_);
  FinalizeAllocatorMap(memory_allocator_map_);
 }

 MemoryAllocator *MemManager::GetMemoryAllocator(rtMemType_t memory_type) {
  std::lock_guard<std::recursive_mutex> lock(allocator_mutex_);
  MemoryAllocator *memory_allocator = nullptr;
  auto it = memory_allocator_map_.find(memory_type);
  if (it != memory_allocator_map_.end()) {
    memory_allocator = it->second;
  }

  // Usually impossible
  if (memory_allocator == nullptr) {
    GELOGE(ACL_ERROR_GE_INTERNAL_ERROR, "GetMemoryAllocator failed, memory type is %u.", memory_type);
    static MemoryAllocator default_memory_allocator(RT_MEMORY_RESERVED);
    return &default_memory_allocator;
  }

  return memory_allocator;
 }

 CachingAllocator &MemManager::CachingInstance(rtMemType_t memory_type) {
  return Instance().GetAllocator(memory_type, caching_allocator_map_);
 }

 RdmaPoolAllocator &MemManager::RdmaPoolInstance(rtMemType_t memory_type) {
  return Instance().GetAllocator(memory_type, rdma_allocator_map_);
 }
 HostMemAllocator &MemManager::HostMemInstance(rtMemType_t memory_type) {
  return Instance().GetAllocator(memory_type, host_allocator_map_);
 }
 }  // namespace ge
--- a/ge/graph/manager/graph_mem_allocator.h
+++ b/ge/graph/manager/graph_mem_allocator.h
@@ -26,7 +26,6 @@

 #include "framework/common/debug/ge_log.h"
 #include "framework/common/ge_inner_error_codes.h"
 #include "graph/manager/host_mem_allocator.h"
 #include "graph/node.h"
 #include "runtime/mem.h"

@@ -71,9 +70,9 @@ class MemoryAllocator {
  /// @ingroup ge_graph
  /// @brief memory allocator init
  /// @param [in] options user config params
  /// @return void
  /// @return Status of init
  ///
  void Initialize(uint32_t device_id = 0);
  Status Initialize(uint32_t device_id = 0);

  ///
  /// @ingroup ge_graph
@@ -136,109 +135,6 @@ class MemoryAllocator {
  bool mem_malloced_;
  map<string, MemoryInfo> memory_base_map_;
 };

 using MemoryAllocatorPtr = std::shared_ptr<MemoryAllocator>;
 class CachingAllocator;
 class RdmaPoolAllocator;
 class MemManager {
 public:
  MemManager();
  virtual ~MemManager();
  static MemManager &Instance();
  static MemoryAllocator *Instance(rtMemType_t memory_type);
  CachingAllocator &CachingInstance(rtMemType_t memory_type);
  RdmaPoolAllocator &RdmaPoolInstance(rtMemType_t memory_type);
  HostMemAllocator &HostMemInstance(rtMemType_t memory_type);
  MemManager(const MemManager &) = delete;
  MemManager &operator=(const MemManager &) = delete;
  ///
  /// @ingroup ge_graph
  /// @brief memory allocator manager init
  /// @param [in] options user config params
  /// @return Status result of function
  ///
  Status Initialize(const std::vector<rtMemType_t> &memory_type);

  ///
  /// @ingroup ge_graph
  /// @brief memory allocator finalize
  /// @return void
  ///
  void Finalize() noexcept;

 private:
  ///
  /// @ingroup ge_graph
  /// @brief ge memory allocator
  /// @param [in] memory_type memory type
  /// @return MemoryAllocator ptr
  ///
  MemoryAllocator *GetMemoryAllocator(rtMemType_t memory_type);

  ///
  /// @ingroup ge_graph
  /// @param [in] memory_type memory type
  /// @param [in] allocate_map memory allocator map
  /// @return Status result of function
  ///
  template <typename T>
  Status InitAllocator(const std::vector<rtMemType_t> &memory_type, std::map<rtMemType_t, T *> &allocate_map) {
    T *allocator = nullptr;
    for (unsigned int index : memory_type) {
      auto it = allocate_map.find(index);
      if (it == allocate_map.end()) {
        allocator = new (std::nothrow) T(index);
        if (allocator != nullptr) {
          allocate_map[index] = allocator;
          GELOGI("Create Allocator memory type[%u] success.", index);
        } else {
          GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Alloc Allocator failed.");
        }
      } else {
        allocator = it->second;
      }

      if (allocator == nullptr) {
        GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Create Allocator failed.");
        return ACL_ERROR_GE_MEMORY_ALLOCATION;
      } else {
        if (allocator->Initialize() != SUCCESS) {
          return ACL_ERROR_GE_INTERNAL_ERROR;
        }
      }
    }
    return SUCCESS;
  }
  ///
  /// @ingroup ge_graph
  /// @param [in] memory_type memory type
  /// @param [in] allocate_map memory allocator map
  /// @return Allocator ptr
  ///
  template <typename T>
  T &GetAllocator(rtMemType_t memory_type, std::map<rtMemType_t, T *> allocate_map) {
    std::lock_guard<std::recursive_mutex> lock(allocator_mutex_);
    T *allocator = nullptr;
    auto it = allocate_map.find(memory_type);
    if (it != allocate_map.end()) {
      allocator = it->second;
    }

    // Usually impossible
    if (allocator == nullptr) {
      GELOGW("Get allocator failed, memory type is %u.", memory_type);
      static T default_allocator(RT_MEMORY_RESERVED);
      return default_allocator;
    }
    return *allocator;
  }

  std::map<rtMemType_t, MemoryAllocator *> memory_allocator_map_;
  std::map<rtMemType_t, CachingAllocator *> caching_allocator_map_;
  std::map<rtMemType_t, RdmaPoolAllocator *> rdma_allocator_map_;
  std::map<rtMemType_t, HostMemAllocator *> host_allocator_map_;
  std::recursive_mutex allocator_mutex_;
 };
 }  // namespace ge

 #endif  // GE_GRAPH_MANAGER_GRAPH_MEM_ALLOCATOR_H_
--- a/ge/graph/manager/graph_mem_manager.cc
+++ b/ge/graph/manager/graph_mem_manager.cc
@@ -0,0 +1,114 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

 #include "graph/manager/graph_mem_manager.h"

 #include <string>

 namespace ge {
 MemManager::MemManager() {}

 MemManager::~MemManager() { Finalize(); }

 MemManager &MemManager::Instance() {
  static MemManager mem_manager;
  return mem_manager;
 }

 Status MemManager::Initialize(const std::vector<rtMemType_t> &memory_type) {
  std::lock_guard<std::recursive_mutex> lock(allocator_mutex_);
  if (init_) {
    GELOGW("MemManager has been inited.");
    return SUCCESS;
  }

  auto ret = InitAllocator(memory_type, memory_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create MemoryAllocator failed.");
    return ret;
  }

  ret = InitAllocator(memory_type, caching_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create CachingAllocator failed.");
    return ret;
  }

  ret = InitAllocator(memory_type, rdma_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create RdmaAllocator failed.");
    return ret;
  }

  ret = InitAllocator(memory_type, host_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create HostMemAllocator failed.");
    return ret;
  }

  ret = InitAllocator(memory_type, session_scope_allocator_map_);
  if (ret != SUCCESS) {
    GELOGE(ret, "Create HostMemAllocator failed.");
    return ret;
  }
  init_ = true;
  return SUCCESS;
 }

 template <typename T>
 void FinalizeAllocatorMap(std::map<rtMemType_t, T *> &allocate_map) {
  for (auto &allocator : allocate_map) {
    if (allocator.second != nullptr) {
      allocator.second->Finalize();
      delete allocator.second;
      allocator.second = nullptr;
    }
  }
  allocate_map.clear();
 }

 void MemManager::Finalize() noexcept {
  GELOGI("Finalize.");
  std::lock_guard<std::recursive_mutex> lock(allocator_mutex_);
  // caching and rdma allocator use memory allocator, so finalize them first
  FinalizeAllocatorMap(session_scope_allocator_map_);
  FinalizeAllocatorMap(caching_allocator_map_);
  FinalizeAllocatorMap(rdma_allocator_map_);
  FinalizeAllocatorMap(host_allocator_map_);
  FinalizeAllocatorMap(memory_allocator_map_);
  init_ = false;
 }

 MemoryAllocator &MemManager::MemInstance(rtMemType_t memory_type) {
  return GetAllocator(memory_type, memory_allocator_map_);
 }

 CachingAllocator &MemManager::CachingInstance(rtMemType_t memory_type) {
  return GetAllocator(memory_type, caching_allocator_map_);
 }

 RdmaPoolAllocator &MemManager::RdmaPoolInstance(rtMemType_t memory_type) {
  return GetAllocator(memory_type, rdma_allocator_map_);
 }

 HostMemAllocator &MemManager::HostMemInstance(rtMemType_t memory_type) {
  return GetAllocator(memory_type, host_allocator_map_);
 }

 SessionScopeMemAllocator &MemManager::SessionScopeMemInstance(rtMemType_t memory_type) {
  return GetAllocator(memory_type, session_scope_allocator_map_);
 }
 }  // namespace ge
--- a/ge/graph/manager/graph_mem_manager.h
+++ b/ge/graph/manager/graph_mem_manager.h
@@ -0,0 +1,141 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

 #ifndef GE_GRAPH_MANAGER_GRAPH_MEM_MANAGER_H_
 #define GE_GRAPH_MANAGER_GRAPH_MEM_MANAGER_H_

 #include <iostream>
 #include <map>
 #include <memory>
 #include <mutex>
 #include <string>
 #include <vector>

 #include "framework/common/debug/ge_log.h"
 #include "framework/common/ge_inner_error_codes.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_caching_allocator.h"
 #include "graph/manager/host_mem_allocator.h"
 #include "graph/manager/rdma_pool_allocator.h"
 #include "graph/manager/host_mem_allocator.h"
 #include "graph/manager/session_scope_mem_allocator.h"
 #include "graph/node.h"
 #include "runtime/mem.h"

 namespace ge {
 using MemoryAllocatorPtr = std::shared_ptr<MemoryAllocator>;

 class MemManager {
 public:
  MemManager();
  virtual ~MemManager();
  static MemManager &Instance();
  MemoryAllocator &MemInstance(rtMemType_t memory_type);
  CachingAllocator &CachingInstance(rtMemType_t memory_type);
  RdmaPoolAllocator &RdmaPoolInstance(rtMemType_t memory_type);
  HostMemAllocator &HostMemInstance(rtMemType_t memory_type);
  SessionScopeMemAllocator &SessionScopeMemInstance(rtMemType_t memory_type);
  MemManager(const MemManager &) = delete;
  MemManager &operator=(const MemManager &) = delete;
  ///
  /// @ingroup ge_graph
  /// @brief memory allocator manager init
  /// @param [in] options user config params
  /// @return Status result of function
  ///
  Status Initialize(const std::vector<rtMemType_t> &memory_type);

  ///
  /// @ingroup ge_graph
  /// @brief memory allocator finalize
  /// @return void
  ///
  void Finalize() noexcept;

  const std::vector<rtMemType_t> &GetAllMemoryType() const { return memory_type_; }

 private:
  ///
  /// @ingroup ge_graph
  /// @param [in] memory_type memory type
  /// @param [in] allocate_map memory allocator map
  /// @return Status result of function
  ///
  template <typename T>
  Status InitAllocator(const std::vector<rtMemType_t> &memory_type, std::map<rtMemType_t, T *> &allocate_map) {
    T *allocator = nullptr;
    for (unsigned int index : memory_type) {
      auto it = allocate_map.find(index);
      if (it == allocate_map.end()) {
        allocator = new (std::nothrow) T(index);
        if (allocator != nullptr) {
          allocate_map[index] = allocator;
          GELOGI("Create Allocator memory type[%u] success.", index);
        } else {
          REPORT_CALL_ERROR("E19999", "New MemoryAllocator fail, index:%u", index);
          GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Alloc Allocator failed.");
        }
      } else {
        allocator = it->second;
      }

      if (allocator == nullptr) {
        GELOGE(ACL_ERROR_GE_MEMORY_ALLOCATION, "Create Allocator failed.");
        return ACL_ERROR_GE_MEMORY_ALLOCATION;
      } else {
        if (allocator->Initialize() != SUCCESS) {
          return ACL_ERROR_GE_INTERNAL_ERROR;
        }
      }
    }
    return SUCCESS;
  }
  ///
  /// @ingroup ge_graph
  /// @param [in] memory_type memory type
  /// @param [in] allocate_map memory allocator map
  /// @return Allocator ptr
  ///
  template <typename T>
  T &GetAllocator(rtMemType_t memory_type, std::map<rtMemType_t, T *> allocate_map) {
    std::lock_guard<std::recursive_mutex> lock(allocator_mutex_);
    T *allocator = nullptr;
    auto it = allocate_map.find(memory_type);
    if (it != allocate_map.end()) {
      allocator = it->second;
    }

    // Usually impossible
    if (allocator == nullptr) {
      GELOGW("Get allocator failed, memory type is %u.", memory_type);
      static T default_allocator(RT_MEMORY_RESERVED);
      return default_allocator;
    }
    return *allocator;
  }

  std::map<rtMemType_t, MemoryAllocator *> memory_allocator_map_;
  std::map<rtMemType_t, CachingAllocator *> caching_allocator_map_;
  std::map<rtMemType_t, RdmaPoolAllocator *> rdma_allocator_map_;
  std::map<rtMemType_t, HostMemAllocator *> host_allocator_map_;
  std::map<rtMemType_t, SessionScopeMemAllocator *> session_scope_allocator_map_;
  std::recursive_mutex allocator_mutex_;
  std::vector<rtMemType_t> memory_type_;
  bool init_ = false;
 };
 }  // namespace ge

 #endif  // GE_GRAPH_MANAGER_GRAPH_MEM_ALLOCATOR_H_
--- a/ge/graph/manager/graph_var_manager.cc
+++ b/ge/graph/manager/graph_var_manager.cc
@@ -17,8 +17,7 @@
 #include "graph/manager/graph_var_manager.h"

 #include "graph/debug/ge_attr_define.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/rdma_pool_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "graph/manager/trans_var_data_utils.h"
 #include "graph/utils/type_utils.h"

@@ -728,7 +727,7 @@ ge::Status VarManager::MallocVarMemory(size_t memory_size) {
  var_memory_size = (var_memory_size + kSessionMemAlignSize - 1) / kSessionMemAlignSize * kSessionMemAlignSize;

  const string purpose("variables and constant op memory in training network.");
  var_mem_base = MemManager::Instance(RT_MEMORY_HBM)->MallocMemory(purpose, memory_key, var_memory_size);
  var_mem_base = MemManager::Instance().MemInstance(RT_MEMORY_HBM).MallocMemory(purpose, memory_key, var_memory_size);
  if (var_mem_base == nullptr) {
    GELOGE(ge::INTERNAL_ERROR,
           "VarManager::MallocVarMemory failed "
@@ -745,7 +744,7 @@ uint8_t *VarManager::GetVarMemoryBase(rtMemType_t memory_type) {
    return MemManager::Instance().RdmaPoolInstance(RT_MEMORY_HBM).GetRdmaBaseAddr();
  }
  string memory_key = std::to_string(session_id_);
  return MemManager::Instance(memory_type)->GetMemoryAddr(memory_key);
  return MemManager::Instance().MemInstance(memory_type).GetMemoryAddr(memory_key);
 }

 uint8_t *VarManager::GetVarMemoryAddr(uint8_t *logic_addr, rtMemType_t memory_type) {
@@ -754,7 +753,7 @@ uint8_t *VarManager::GetVarMemoryAddr(uint8_t *logic_addr, rtMemType_t memory_ty
    return logic_addr;
  }
  string mem_key = std::to_string(session_id_);
  uint8_t *mem_base = MemManager::Instance(memory_type)->GetMemoryAddr(mem_key);
  uint8_t *mem_base = MemManager::Instance().MemInstance(memory_type).GetMemoryAddr(mem_key);
  if (mem_base == nullptr) {
    return nullptr;
  }
@@ -766,7 +765,7 @@ uint8_t *VarManager::GetVarMemoryAddr(uint8_t *logic_addr, rtMemType_t memory_ty
 ge::Status VarManager::FreeVarMemory() {
  std::lock_guard<std::recursive_mutex> lock(mutex_);
  string memory_key = std::to_string(SessionId());
  return MemManager::Instance(RT_MEMORY_HBM)->FreeMemory(memory_key);
  return MemManager::Instance().MemInstance(RT_MEMORY_HBM).FreeMemory(memory_key);
 }

 ge::Status VarManager::SetTransRoad(const std::string &var_name, const VarTransRoad &trans_road) {
--- a/ge/graph/manager/memory_api.cc
+++ b/ge/graph/manager/memory_api.cc
@@ -19,7 +19,7 @@
 #include <memory>

 #include "common/ge/plugin_manager.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "graph/manager/host_mem_manager.h"
 #include "graph/manager/rdma_pool_allocator.h"
 #include "graph/utils/type_utils.h"
--- a/ge/graph/manager/rdma_pool_allocator.cc
+++ b/ge/graph/manager/rdma_pool_allocator.cc
@@ -20,6 +20,7 @@
 #include "framework/common/debug/ge_log.h"
 #include "graph/ge_context.h"
 #include "runtime/dev.h"
 #include "graph/manager/graph_mem_manager.h"

 namespace {
 const size_t kAlignedSize = 512;
@@ -49,7 +50,7 @@ RdmaPoolAllocator::RdmaPoolAllocator(rtMemType_t memory_type)
      })) {}

 Status RdmaPoolAllocator::Initialize() {
  memory_allocator_ = MemManager::Instance(memory_type_);
  memory_allocator_ = &MemManager::Instance().MemInstance(memory_type_);
  if (memory_allocator_ == nullptr) {
    return ACL_ERROR_GE_INTERNAL_ERROR;
  }
--- a/ge/graph/manager/session_scope_mem_allocator.cc
+++ b/ge/graph/manager/session_scope_mem_allocator.cc
@@ -0,0 +1,85 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

 #include "graph/manager/session_scope_mem_allocator.h"

 #include <set>
 #include <string>
 #include <utility>

 #include "framework/common/debug/ge_log.h"
 #include "graph/manager/graph_mem_manager.h"

 namespace ge {

 SessionScopeMemAllocator::SessionScopeMemAllocator(rtMemType_t memory_type)
    : memory_type_(memory_type), memory_allocator_(nullptr) {}

 Status SessionScopeMemAllocator::Initialize(uint32_t device_id) {
  GELOGI("Device id %u", device_id);
  // when redo Initialize free old memory
  FreeAllMemory();
  std::lock_guard<std::recursive_mutex> lock(mutex_);
  memory_allocator_ = &MemManager::Instance().MemInstance(memory_type_);
  if (memory_allocator_ == nullptr) {
    return ACL_ERROR_GE_INTERNAL_ERROR;
  }
  return ge::SUCCESS;
 }

 void SessionScopeMemAllocator::Finalize(uint32_t device_id) {
  GELOGI("Device id %u", device_id);
  FreeAllMemory();
 }

 uint8_t *SessionScopeMemAllocator::Malloc(size_t size, uint64_t session_id, uint32_t device_id) {
  GELOGI("Start malloc memory, size:%zu, session id:%lu device id:%u", size, session_id, device_id);
  const std::string purpose = "Memory for session scope.";
  auto ptr = memory_allocator_->MallocMemory(purpose, size, device_id);
  if (ptr == nullptr) {
    GELOGE(ge::FAILED, "Malloc failed, no enough memory for size:%zu, session_id:%lu device_id:%u", size,
           session_id, device_id);
    return nullptr;
  }
  std::lock_guard<std::recursive_mutex> lock(mutex_);
  std::shared_ptr<uint8_t> mem_ptr(ptr, [&](uint8_t *p) { (void)memory_allocator_->FreeMemory(p); });
  allocated_memory_[session_id].emplace_back(size, mem_ptr);
  return ptr;
 }

 Status SessionScopeMemAllocator::Free(uint64_t session_id, uint32_t device_id) {
  GELOGI("Free session:%lu memory, device id:%u.", session_id, device_id);
  std::lock_guard<std::recursive_mutex> lock(mutex_);
  auto it = allocated_memory_.find(session_id);
  if (it == allocated_memory_.end()) {
    REPORT_INNER_ERROR("E19999", "Param memory not allocated before, session_id:%lu device_id:%u, check invalid",
                       session_id, device_id);
    GELOGE(PARAM_INVALID, "Invalid session_id");
    return ge::PARAM_INVALID;
  }
  allocated_memory_.erase(it);
  return ge::SUCCESS;
 }

 void SessionScopeMemAllocator::FreeAllMemory() {
  GELOGI("Free all memory");
  std::lock_guard<std::recursive_mutex> lock(mutex_);
  for (auto &session_mem : allocated_memory_) {
    session_mem.second.clear();
  }
  allocated_memory_.clear();
 }
 }  // namespace ge
--- a/ge/graph/manager/session_scope_mem_allocator.h
+++ b/ge/graph/manager/session_scope_mem_allocator.h
@@ -0,0 +1,123 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

 #ifndef GE_GRAPH_MANAGER_SESSION_SCOPE_MEM_ALLOCATOR_H_
 #define GE_GRAPH_MANAGER_SESSION_SCOPE_MEM_ALLOCATOR_H_

 #include <iostream>
 #include <map>
 #include <memory>
 #include <mutex>
 #include <string>
 #include <vector>
 #include <unordered_map>
 #include <functional>

 #include "framework/common/ge_inner_error_codes.h"
 #include "graph/node.h"
 #include "graph/manager/block_memory.h"
 #include "runtime/mem.h"
 #include "graph/manager/graph_mem_allocator.h"

 namespace ge {
 class SessionScopeMemoryInfo {
 public:
  SessionScopeMemoryInfo(size_t size, const std::shared_ptr<uint8_t> &ptr) : size(size), ptr(ptr) {}
  SessionScopeMemoryInfo() = delete;
  virtual ~SessionScopeMemoryInfo() = default;

  SessionScopeMemoryInfo(const SessionScopeMemoryInfo &other) {
    if (&other == this) {
      return;
    }
    size = other.size;
    ptr = other.ptr;
  };

  SessionScopeMemoryInfo &operator=(const SessionScopeMemoryInfo &other) {
    if (&other == this) {
      return *this;
    }
    size = other.size;
    ptr = other.ptr;
  };

 private:
  size_t size = 0;
  std::shared_ptr<uint8_t> ptr = nullptr;
 };

 class SessionScopeMemAllocator {
 public:
  explicit SessionScopeMemAllocator(rtMemType_t memory_type);

  SessionScopeMemAllocator(const SessionScopeMemAllocator &) = delete;

  SessionScopeMemAllocator &operator=(const SessionScopeMemAllocator &) = delete;

  virtual ~SessionScopeMemAllocator() = default;

  ///
  /// @ingroup ge_graph
  /// @brief caching allocator init
  /// @param [in] device id
  /// @return Status of init
  ///
  Status Initialize(uint32_t device_id = 0);

  ///
  /// @ingroup ge_graph
  /// @brief memory allocator finalize, release all memory
  /// @return void
  ///
  void Finalize(uint32_t device_id = 0);

  ///
  /// @ingroup ge_graph
  /// @brief malloc memory
  /// @param [in] size memory size
  /// @param [in] session_id session id
  /// @param [in] device id
  /// @return  memory address
  ///
  uint8_t *Malloc(size_t size, uint64_t session_id, uint32_t device_id = 0);

  ///
  /// @ingroup ge_graph
  /// @brief free memory
  /// @param [in] session_id session id
  /// @param [in] device_id device id
  /// @return Status result of function
  ///
  Status Free(uint64_t session_id, uint32_t device_id = 0);

 private:
  void FreeAllMemory();

 private:
  rtMemType_t memory_type_;

  // device memory allocator
  MemoryAllocator *memory_allocator_;

  // lock around all operations
  mutable std::recursive_mutex mutex_;

  // allocated blocks by memory pointer
  std::unordered_map<uint64_t, std::vector<SessionScopeMemoryInfo>> allocated_memory_;
 };
 }  // namespace ge
 #endif  // GE_GRAPH_MANAGER_SESSION_SCOPE_MEM_ALLOCATOR_H_
--- a/ge/hybrid/common/npu_memory_allocator.cc
+++ b/ge/hybrid/common/npu_memory_allocator.cc
@@ -17,10 +17,7 @@
 #include "npu_memory_allocator.h"
 #include <mutex>
 #include "framework/common/debug/log.h"
 #include "graph/manager/graph_caching_allocator.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/rdma_pool_allocator.h"
 #include "graph/manager/host_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"

 namespace ge {
 namespace hybrid {
--- a/ge/hybrid/model/hybrid_model_builder.cc
+++ b/ge/hybrid/model/hybrid_model_builder.cc
@@ -26,8 +26,7 @@
 #include "graph/manager/graph_var_manager.h"
 #include "graph/manager/host_mem_manager.h"
 #include "graph/manager/trans_var_data_utils.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/host_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "graph/utils/graph_utils.h"
 #include "hybrid/common/npu_memory_allocator.h"
 #include "hybrid/node_executor/node_executor.h"
--- a/ge/hybrid/node_executor/host_cpu/host_cpu_node_executor.cc
+++ b/ge/hybrid/node_executor/host_cpu/host_cpu_node_executor.cc
@@ -18,8 +18,7 @@
 #include "hybrid/node_executor/host_cpu/kernel_factory.h"
 #include "graph/passes/folding_pass.h"
 #include "hybrid/model/hybrid_model.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/host_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "ge_local_engine/engine/host_cpu_engine.h"

 namespace ge {
--- a/ge/init/gelib.cc
+++ b/ge/init/gelib.cc
@@ -39,7 +39,7 @@
 #include "graph/ge_context.h"
 #include "graph/ge_global_options.h"
 #include "graph/load/model_manager/model_manager.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "graph/manager/host_mem_manager.h"
 #include "graph/manager/graph_var_manager.h"
 #include "runtime/kernel.h"
--- a/ge/session/inner_session.cc
+++ b/ge/session/inner_session.cc
@@ -32,6 +32,7 @@
 #include "graph/common/local_context.h"
 #include "graph/load/model_manager/model_manager.h"
 #include "graph/manager/graph_var_manager.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "graph/utils/tensor_adapter.h"
 #include "runtime/mem.h"

@@ -155,6 +156,11 @@ Status InnerSession::Finalize() {
  // release var memory
  GELOGI("VarManager free var memory.");
  (void)VarManager::Instance(session_id_)->FreeVarMemory();

  for (auto memory_type : MemManager::Instance().GetAllMemoryType()) {
    (void)MemManager::Instance().SessionScopeMemInstance(memory_type).Free(session_id_);
  }

  // release analyzer saved info(Session Level)
  Analyzer::GetInstance()->DestroySessionJsonObject(session_id_);

--- a/ge/single_op/single_op_manager.cc
+++ b/ge/single_op/single_op_manager.cc
@@ -19,8 +19,7 @@
 #include <mutex>
 #include <string>

 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_caching_allocator.h"
 #include "graph/manager/graph_mem_manager.h"

 namespace ge {
 FMK_FUNC_HOST_VISIBILITY FMK_FUNC_DEV_VISIBILITY SingleOpManager::~SingleOpManager() {
--- a/inc/framework/memory/memory_assigner.h
+++ b/inc/framework/memory/memory_assigner.h
@@ -33,7 +33,7 @@ class GE_FUNC_VISIBILITY MemoryAssigner {

  MemoryAssigner &operator=(const MemoryAssigner &) = delete;

  Status AssignMemory(bool is_loop_graph, map<int64_t, size_t> &mem_offset, size_t &zero_copy_mem_size);
  Status AssignMemory(bool is_loop_graph, map<uint64_t, size_t> &mem_offset, size_t &zero_copy_mem_size);

 private:
  ge::ComputeGraphPtr compute_graph_;
--- a/tests/ut/ge/CMakeLists.txt
+++ b/tests/ut/ge/CMakeLists.txt
@@ -337,8 +337,10 @@ set(COMMON_SRC_FILES
    "${GE_CODE_DIR}/ge/graph/manager/trans_var_data_utils.cc"
    "${GE_CODE_DIR}/ge/graph/common/local_context.cc"
    "${GE_CODE_DIR}/ge/graph/manager/graph_caching_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/session_scope_mem_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/rdma_pool_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/host_mem_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/graph_mem_manager.cc"
    "${GE_CODE_DIR}/ge/common/dump/dump_op.cc"
    "${GE_CODE_DIR}/ge/common/model_saver.cc"
    "${GE_CODE_DIR}/ge/hybrid/node_executor/aicpu/aicpu_ext_info.cc"
@@ -396,8 +398,10 @@ set(GRAPH_LOAD_COMMON_SRC_FILES
    "${GE_CODE_DIR}/ge/graph/manager/graph_var_manager.cc"
    "${GE_CODE_DIR}/ge/graph/manager/trans_var_data_utils.cc"
    "${GE_CODE_DIR}/ge/graph/manager/graph_caching_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/session_scope_mem_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/rdma_pool_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/host_mem_allocator.cc"
    "${GE_CODE_DIR}/ge/graph/manager/graph_mem_manager.cc"
    "${GE_CODE_DIR}/ge/common/thread_pool.cc"
 )

@@ -792,6 +796,7 @@ set(MULTI_PARTS_TEST_FILES
    "graph/preprocess/graph_preprocess_unittest.cc"
    "graph/manager/hcom_util_unittest.cc"
    "graph/manager/graph_caching_allocator_unittest.cc"
    "graph/manager/session_scope_mem_allocator_unittest.cc"
    "graph/manager/run_graph_unittest.cc"
    "graph/partition/dynamic_shape_partition_unittest.cc"
    "graph/manager/graph_manager_unittest.cc"
@@ -824,6 +829,7 @@ set(PROFILING_MNG_TEST_FILES
 set(HYBRID_TEST_FILES
    "hybrid/ge_hybrid_unittest.cc"
    "hybrid/known_node_executor_unittest.cc"
    "hybrid/executor/worker/execution_engine_unittest.cc"
    "hybrid/executor/subgraph_executor_unittest.cc"
    "hybrid/executor/worker/execution_engine_unittest.cc"
    "hybrid/model/hybrid_model_builder_unittest.cc"
--- a/tests/ut/ge/graph/build/mem_assigner_unittest.cc
+++ b/tests/ut/ge/graph/build/mem_assigner_unittest.cc
@@ -44,7 +44,8 @@ using domi::GetContext;

 class UtestMemoryAssignerTest : public testing::Test {
 public:
  ge::OpDescPtr CreateOpWithWsSize(const string &name, int64_t wsByte, const string &type = "some", int64_t size = 1024) {
  ge::OpDescPtr CreateOpWithWsSize(const string &name, int64_t wsByte, const string &type = "some",
                                   int64_t size = 1024) {
    ge::OpDescPtr op_def = make_shared<ge::OpDesc>(name, type);
    auto desc_temp_ptr = make_shared<ge::GeTensorDesc>();
    auto desc_temp = *desc_temp_ptr;
@@ -214,7 +215,8 @@ class UtestMemoryAssignerTest : public testing::Test {

    return builder.GetGraph();
  }
  void make_ffts_reuse_graph(ge::ComputeGraphPtr graph, int32_t thread_scope_id_1 = kInvalidThreadScopeId,

  void MakeFftsReuseGraph(ge::ComputeGraphPtr graph, int32_t thread_scope_id_1 = kInvalidThreadScopeId,
                            int32_t thread_scope_id_2 = kInvalidThreadScopeId) {
    ge::OpDescPtr op_def_a = CreateOpWithWsSize("A", 512);
    ge::OpDescPtr op_def_b = CreateOpWithWsSize("B", 0);
@@ -253,28 +255,119 @@ class UtestMemoryAssignerTest : public testing::Test {
    graph->TopologicalSorting();
  }

  void MakeSessionScopeReuseGraph(ge::ComputeGraphPtr graph) {
    ge::OpDescPtr op_def_a = CreateOpWithWsSize("A", 512);
    ge::OpDescPtr op_def_b = CreateOpWithWsSize("B", 0);
    ge::OpDescPtr op_def_c = CreateOpWithWsSize("C", 512);
    ge::OpDescPtr op_def_d = CreateOpWithWsSize("D", 512);
    ge::OpDescPtr op_def_e = CreateOpWithWsSize("E", 1024);
    ge::OpDescPtr op_def_f = CreateOpWithWsSize("F", 512, "some", 2048UL);
    ge::OpDescPtr op_def_g = CreateOpWithWsSize("G", 0);

    std::vector<int64_t> workspace_bytes;
    workspace_bytes.push_back(1024);
    workspace_bytes.push_back(512);
    op_def_c->SetWorkspaceBytes(workspace_bytes);
    vector<int32_t> workspace_no_reuse_scope = { 0 , 1 };
    (void)ge::AttrUtils::SetListInt(op_def_c, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope);

    vector<int32_t> workspace_no_reuse_scope_e = { 1 };
    (void)ge::AttrUtils::SetListInt(op_def_e, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope_e);

    ge::NodePtr node_a = graph->AddNode(op_def_a);
    ge::NodePtr node_b = graph->AddNode(op_def_b);
    ge::NodePtr node_c = graph->AddNode(op_def_c);
    ge::NodePtr node_d = graph->AddNode(op_def_d);
    ge::NodePtr node_e = graph->AddNode(op_def_e);
    ge::NodePtr node_f = graph->AddNode(op_def_f);
    ge::NodePtr node_g = graph->AddNode(op_def_g);

    ge::GraphUtils::AddEdge(node_a->GetOutDataAnchor(0), node_b->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_b->GetOutDataAnchor(0), node_c->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_c->GetOutDataAnchor(0), node_d->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_d->GetOutDataAnchor(0), node_e->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_e->GetOutDataAnchor(0), node_f->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_f->GetOutDataAnchor(0), node_g->GetInDataAnchor(0));
    graph->TopologicalSorting();
  }

 void MakeContinuousReuseGraph(ge::ComputeGraphPtr graph, bool nopading = false) {
    ge::OpDescPtr op_def_a = CreateOpWithWsSize("A", 512);
    ge::OpDescPtr op_def_b = CreateOpWithWsSize("B", 0);
    ge::OpDescPtr op_def_c = CreateOpWithWsSize("C", 512);
    ge::OpDescPtr op_def_d = CreateOpWithWsSize("D", 512);
    ge::OpDescPtr op_def_e = CreateOpWithWsSize("E", 1024);
    ge::OpDescPtr op_def_f = CreateOpWithWsSize("F", 512, "some", 2048UL);
    ge::OpDescPtr op_def_g = CreateOpWithWsSize("G", 0);

    if (nopading) {
      (void)ge::AttrUtils::SetBool(op_def_d, ATTR_NAME_NOPADDING_CONTINUOUS_INPUT, true);
      (void)ge::AttrUtils::SetBool(op_def_d, ATTR_NAME_NOPADDING_CONTINUOUS_OUTPUT, true);
      (void)ge::AttrUtils::SetBool(op_def_d, ATTR_NAME_OUTPUT_REUSE_INPUT, true);
      (void)ge::AttrUtils::SetInt(op_def_d, ATTR_NAME_REUSE_INPUT_ON_DIM_INDEX, 0);
    } else {
      (void)ge::AttrUtils::SetBool(op_def_d, ATTR_NAME_CONTINUOUS_INPUT, true);
      (void)ge::AttrUtils::SetBool(op_def_d, ATTR_NAME_CONTINUOUS_OUTPUT, true);
    }

    ge::NodePtr node_a = graph->AddNode(op_def_a);
    ge::NodePtr node_b = graph->AddNode(op_def_b);
    ge::NodePtr node_c = graph->AddNode(op_def_c);
    ge::NodePtr node_d = graph->AddNode(op_def_d);
    ge::NodePtr node_e = graph->AddNode(op_def_e);
    ge::NodePtr node_f = graph->AddNode(op_def_f);
    ge::NodePtr node_g = graph->AddNode(op_def_g);

    ge::GraphUtils::AddEdge(node_a->GetOutDataAnchor(0), node_d->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_b->GetOutDataAnchor(0), node_d->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_c->GetOutDataAnchor(0), node_d->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_d->GetOutDataAnchor(0), node_e->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_d->GetOutDataAnchor(0), node_f->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_d->GetOutDataAnchor(0), node_g->GetInDataAnchor(0));
    graph->TopologicalSorting();
  }

  void MakeMultiBatchReuseGraph(ge::ComputeGraphPtr graph) {
    ge::OpDescPtr op_def_a = CreateOpWithWsSize("A", 512);
    ge::OpDescPtr op_def_b = CreateOpWithWsSize("B", 0);
    ge::OpDescPtr op_def_c = CreateOpWithWsSize("C", 512);
    ge::OpDescPtr op_def_d = CreateOpWithWsSize("D", 512);
    ge::OpDescPtr op_def_e = CreateOpWithWsSize("E", 1024);
    ge::OpDescPtr op_def_f = CreateOpWithWsSize("F", 512, "some", 2048UL);
    ge::OpDescPtr op_def_g = CreateOpWithWsSize("G", 0);

   (void)ge::AttrUtils::SetStr(op_def_b, ATTR_NAME_BATCH_LABEL, "Batch_0");
   (void)ge::AttrUtils::SetStr(op_def_c, ATTR_NAME_BATCH_LABEL, "Batch_0");
   (void)ge::AttrUtils::SetStr(op_def_e, ATTR_NAME_BATCH_LABEL, "Batch_1");
   (void)ge::AttrUtils::SetStr(op_def_f, ATTR_NAME_BATCH_LABEL, "Batch_1");
   vector<int32_t> workspace_no_reuse_scope = { 1 };
   (void)ge::AttrUtils::SetListInt(op_def_c, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope);
   (void)ge::AttrUtils::SetListInt(op_def_e, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope);

    ge::NodePtr node_a = graph->AddNode(op_def_a);
    ge::NodePtr node_b = graph->AddNode(op_def_b);
    ge::NodePtr node_c = graph->AddNode(op_def_c);
    ge::NodePtr node_d = graph->AddNode(op_def_d);
    ge::NodePtr node_e = graph->AddNode(op_def_e);
    ge::NodePtr node_f = graph->AddNode(op_def_f);
    ge::NodePtr node_g = graph->AddNode(op_def_g);

    ge::GraphUtils::AddEdge(node_a->GetOutDataAnchor(0), node_b->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_b->GetOutDataAnchor(0), node_c->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_c->GetOutDataAnchor(0), node_d->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_a->GetOutDataAnchor(0), node_e->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_e->GetOutDataAnchor(0), node_f->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_f->GetOutDataAnchor(0), node_d->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_d->GetOutDataAnchor(0), node_g->GetInDataAnchor(0));
    graph->TopologicalSorting();
  }

 protected:
  void SetUp() {}

  void TearDown() { GetContext().out_nodes_map.clear(); }
 };

 /*
 TEST_F(UtestMemoryAssignerTest, MemoryBlock_Resize_RealSizeList_is_empty) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  ge::OpDescPtr op_def_a = CreateOpWithWsSize("A", 6000);
  ge::NodePtr node_a = graph->AddNode(op_def_a);
  MemoryBlock* memory_block = new MemoryBlock(0);
  memory_block->Init(1, kOutput, node_a, 0, 1);
  memory_block->real_size_list_.clear();
  memory_block->Resize();

  EXPECT_EQ(memory_block->Size(), 0);

  delete memory_block;
 }
 */

 namespace ge {

 class MockBlockMemAssigner : public BlockMemAssigner {
@@ -313,12 +406,44 @@ TEST_F(UtestMemoryAssignerTest, graph_memory_assign_continuous_input) {
  EXPECT_EQ(addn2->GetOpDesc()->GetOutputOffset()[0], 600);
 }

 TEST_F(UtestMemoryAssignerTest, block_memory_assign_nopading_continuous_memory) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  MakeContinuousReuseGraph(graph, true);
  HybridMemAssigner hybridMemAssigner(graph);
  ge::Status ret = hybridMemAssigner.Assign();
  size_t offset = 0;
  auto it = hybridMemAssigner.GetMemOffsets().find(RT_MEMORY_HBM);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    offset = it->second;
  }

  EXPECT_EQ(offset, 8192);
  EXPECT_EQ(ret, SUCCESS);
 }

 TEST_F(UtestMemoryAssignerTest, block_memory_assign_continuous_memory) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  MakeContinuousReuseGraph(graph);
  map<uint64_t, size_t> mem_offset;
  size_t zero_copy_mem_size = 0;
  MemoryAssigner memoryAssigner(graph);
  ge::Status ret = memoryAssigner.AssignMemory(false, mem_offset, zero_copy_mem_size);
  size_t offset = 0;
  auto it = mem_offset.find(RT_MEMORY_HBM);
  if (it != mem_offset.end()) {
    offset = it->second;
  }

  EXPECT_EQ(offset, 11264);
  EXPECT_EQ(ret, SUCCESS);
 }

 TEST_F(UtestMemoryAssignerTest, graph_memory_set_last_used_attr) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  MakeGraph(graph);
  auto node_f = graph->FindNode("F");
  MemoryAssigner memory_assigner(graph);
  map<int64_t, size_t> mem_offset;
  map<uint64_t, size_t> mem_offset;
  size_t zero_memory_size = 0;
  EXPECT_EQ(memory_assigner.AssignMemory(false, mem_offset, zero_memory_size), GRAPH_SUCCESS);

@@ -335,7 +460,7 @@ TEST_F(UtestMemoryAssignerTest, graph_memory_assign_ref_var) {
  std::string value = "A";
  (void) ge::AttrUtils::SetStr(node_b->GetOpDesc()->MutableOutputDesc(0), REF_VAR_SRC_VAR_NAME, value);
  MemoryAssigner memory_assigner(graph);
  map<int64_t, size_t> mem_offset;
  map<uint64_t, size_t> mem_offset;
  size_t zero_memory_size = 0;
  VarManager::Instance(0)->Init(0, 0, 0, 0);
  EXPECT_EQ(memory_assigner.AssignMemory(false, mem_offset, zero_memory_size), GRAPH_SUCCESS);
@@ -356,7 +481,7 @@ TEST_F(UtestMemoryAssignerTest, graph_memory_assign_ref_var_not_found) {
  std::string value = "M";
  (void) ge::AttrUtils::SetStr(node_b->GetOpDesc()->MutableOutputDesc(0), REF_VAR_SRC_VAR_NAME, value);
  MemoryAssigner memory_assigner(graph);
  map<int64_t, size_t> mem_offset;
  map<uint64_t, size_t> mem_offset;
  size_t zero_memory_size = 0;
  VarManager::Instance(0)->Init(0, 0, 0, 0);
  EXPECT_NE(memory_assigner.AssignMemory(false, mem_offset, zero_memory_size), GRAPH_SUCCESS);
@@ -460,30 +585,86 @@ TEST_F(UtestMemoryAssignerTest, graph_memory_assign_atomic_output_and_workspace)

 TEST_F(UtestMemoryAssignerTest, Mock_ffts_reuse_no_functinon_op) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  make_ffts_reuse_graph(graph, kInvalidThreadScopeId, kInvalidThreadScopeId);
  MakeFftsReuseGraph(graph, kInvalidThreadScopeId, kInvalidThreadScopeId);
  HybridMemAssigner hybridMemAssigner(graph);
  ge::Status ret = hybridMemAssigner.Assign();
  size_t offset = hybridMemAssigner.GetMemOffset();
  size_t offset = 0;
  auto it = hybridMemAssigner.GetMemOffsets().find(RT_MEMORY_HBM);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    offset = it->second;
  }
  EXPECT_EQ(offset, 5120);
  EXPECT_EQ(ret, SUCCESS);
 }

 TEST_F(UtestMemoryAssignerTest, Mock_ffts_reuse_two_functinon_op) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  make_ffts_reuse_graph(graph, 0, 1);
  MakeFftsReuseGraph(graph, 0, 1);
  HybridMemAssigner hybridMemAssigner(graph);
  ge::Status ret = hybridMemAssigner.Assign();
  size_t offset = hybridMemAssigner.GetMemOffset();
  size_t offset = 0;
  auto it = hybridMemAssigner.GetMemOffsets().find(RT_MEMORY_HBM);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    offset = it->second;
  }
  EXPECT_EQ(offset, 6656);
  EXPECT_EQ(ret, SUCCESS);
 }

 TEST_F(UtestMemoryAssignerTest, Mock_ffts_reuse_one_functinon_op) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  make_ffts_reuse_graph(graph, 0, kInvalidThreadScopeId);
  MakeFftsReuseGraph(graph, 0, kInvalidThreadScopeId);
  HybridMemAssigner hybridMemAssigner(graph);
  ge::Status ret = hybridMemAssigner.Assign();
  size_t offset = hybridMemAssigner.GetMemOffset();
  size_t offset = 0;
  auto it = hybridMemAssigner.GetMemOffsets().find(RT_MEMORY_HBM);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    offset = it->second;
  }
  EXPECT_EQ(offset, 5632);
  EXPECT_EQ(ret, SUCCESS);
 }

 TEST_F(UtestMemoryAssignerTest, one_session_scope_op) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  MakeSessionScopeReuseGraph(graph);
  HybridMemAssigner hybridMemAssigner(graph);
  ge::Status ret = hybridMemAssigner.Assign();
  size_t offset = 0;
  auto it = hybridMemAssigner.GetMemOffsets().find(RT_MEMORY_HBM);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    offset = it->second;
  }

  auto mem_type_session_scope = (kSessionScopeMemory | RT_MEMORY_HBM);
  size_t session_scope_offset = 0;
  it = hybridMemAssigner.GetMemOffsets().find(mem_type_session_scope);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    session_scope_offset = it->second;
  }
  EXPECT_EQ(offset, 5120);
  EXPECT_EQ(session_scope_offset, 1536);
  EXPECT_EQ(ret, SUCCESS);
 }

 TEST_F(UtestMemoryAssignerTest, multi_batch_reuse) {
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  MakeMultiBatchReuseGraph(graph);
  HybridMemAssigner hybridMemAssigner(graph);
  ge::Status ret = hybridMemAssigner.Assign();
  size_t offset = 0;
  auto it = hybridMemAssigner.GetMemOffsets().find(RT_MEMORY_HBM);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    offset = it->second;
  }

  auto mem_type_session_scope = (kSessionScopeMemory | RT_MEMORY_HBM);
  size_t session_scope_offset = 0;
  it = hybridMemAssigner.GetMemOffsets().find(mem_type_session_scope);
  if (it != hybridMemAssigner.GetMemOffsets().end()) {
    session_scope_offset = it->second;
  }
  EXPECT_EQ(offset, 6656);
  EXPECT_EQ(session_scope_offset, 1536);
  EXPECT_EQ(ret, SUCCESS);
 }
--- a/tests/ut/ge/graph/build/model_builder_unittest.cc
+++ b/tests/ut/ge/graph/build/model_builder_unittest.cc
@@ -30,6 +30,7 @@
 #define protected public
 #define private public
 #include "graph/build/model_builder.h"
 #include "memory/memory_assigner.h"
 #undef protected
 #undef private

@@ -127,6 +128,41 @@ class UtestModelBuilderTest : public testing::Test {
    graph->TopologicalSorting();
  }

 void MakeSessionScopeReuseGraph(ge::ComputeGraphPtr graph) {
    ge::OpDescPtr op_def_a = CreateOpWithWsSize("A", 512);
    ge::OpDescPtr op_def_b = CreateOpWithWsSize("B", 0);
    ge::OpDescPtr op_def_c = CreateOpWithWsSize("C", 512);
    ge::OpDescPtr op_def_d = CreateOpWithWsSize("D", 512);
    ge::OpDescPtr op_def_e = CreateOpWithWsSize("E", 1024);
    ge::OpDescPtr op_def_f = CreateOpWithWsSize("F", 512);
    ge::OpDescPtr op_def_g = CreateOpWithWsSize("G", 0);

    std::vector<int64_t> workspace_bytes;
    workspace_bytes.push_back(1024);
    workspace_bytes.push_back(512);
    op_def_c->SetWorkspaceBytes(workspace_bytes);
    vector<int32_t> workspace_no_reuse_scope = { 0 , 1 };
    (void)ge::AttrUtils::SetListInt(op_def_c, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope);

    vector<int32_t> workspace_no_reuse_scope_e = { 1 };
    (void)ge::AttrUtils::SetListInt(op_def_e, ATTR_NAME_WORKSPACE_MEMORY_NO_REUSE_SCOPE, workspace_no_reuse_scope_e);

    ge::NodePtr node_a = graph->AddNode(op_def_a);
    ge::NodePtr node_b = graph->AddNode(op_def_b);
    ge::NodePtr node_c = graph->AddNode(op_def_c);
    ge::NodePtr node_d = graph->AddNode(op_def_d);
    ge::NodePtr node_e = graph->AddNode(op_def_e);
    ge::NodePtr node_f = graph->AddNode(op_def_f);
    ge::NodePtr node_g = graph->AddNode(op_def_g);

    ge::GraphUtils::AddEdge(node_a->GetOutDataAnchor(0), node_b->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_b->GetOutDataAnchor(0), node_c->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_c->GetOutDataAnchor(0), node_d->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_d->GetOutDataAnchor(0), node_e->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_e->GetOutDataAnchor(0), node_f->GetInDataAnchor(0));
    ge::GraphUtils::AddEdge(node_f->GetOutDataAnchor(0), node_g->GetInDataAnchor(0));
    graph->TopologicalSorting();
  }

 protected:
  void SetUp() {}
@@ -162,6 +198,24 @@ TEST_F(UtestModelBuilderTest, test_save_atomic_bin) {
  EXPECT_EQ(builder.SaveAtomicTBEKernel(op_desc), SUCCESS);
 }

 TEST_F(UtestModelBuilderTest, build_model_for_get_task) {
  Graph2SubGraphInfoList subgraphs;
  std::map<std::string, int> stream_max_parallel_num;
  ge::ComputeGraphPtr graph = make_shared<ge::ComputeGraph>("");
  MakeSessionScopeReuseGraph(graph);
  std::map<std::string, std::string> option;
  ge::ModelBuilder builder(0, graph, subgraphs, stream_max_parallel_num, false);

  MemoryAssigner mem_assigner(graph);
  EXPECT_EQ(mem_assigner.AssignMemory(false, builder.mem_type_to_mem_offset_, builder.zero_copy_mem_size_), SUCCESS);

  ge::Model model;
  EXPECT_EQ(builder.BuildModelDef(model), SUCCESS);
  int64_t session_scope_mem_offset = 0;
  ge::AttrUtils::GetInt(&model, ATTR_MODEL_SESSION_SCOPE_MEMORY_SIZE, session_scope_mem_offset);
  EXPECT_EQ(session_scope_mem_offset, 1536);
 }

 TEST_F(UtestModelBuilderTest, test_model_save) {
  Graph2SubGraphInfoList subgraphs;
  std::map<std::string, int> stream_max_parallel_num;
--- a/tests/ut/ge/graph/ge_executor_unittest.cc
+++ b/tests/ut/ge/graph/ge_executor_unittest.cc
@@ -43,6 +43,7 @@
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/utils/graph_utils.h"
 #include "proto/ge_ir.pb.h"
 #include "graph/manager/graph_var_manager.h"
 #undef private
 #undef protected

@@ -194,6 +195,11 @@ TEST_F(UtestGeExecutor, kernel_ex_InitDumpTask) {
 }

 TEST_F(UtestGeExecutor, execute_graph_with_stream) {
  VarManager::Instance(0)->Init(0, 0, 0, 0);
  map<string, string> options;
  options[GRAPH_MEMORY_MAX_SIZE] = "1048576";
  VarManager::Instance(0)->SetMemoryMallocSize(options);

  DavinciModel model(0, nullptr);
  ComputeGraphPtr graph = make_shared<ComputeGraph>("default");

@@ -278,7 +284,6 @@ TEST_F(UtestGeExecutor, execute_graph_with_stream) {
  OutputData output_data;
  vector<Tensor> outputs;
  EXPECT_EQ(model.GenOutputTensorInfo(&output_data, outputs), SUCCESS);
  

  GraphExecutor graph_executer;
  graph_executer.init_flag_ = true;
--- a/tests/ut/ge/graph/manager/graph_caching_allocator_unittest.cc
+++ b/tests/ut/ge/graph/manager/graph_caching_allocator_unittest.cc
@@ -28,8 +28,7 @@

 #define protected public
 #define private public
 #include "graph/manager/graph_caching_allocator.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #undef protected
 #undef private

--- a/tests/ut/ge/graph/manager/session_scope_mem_allocator_unittest.cc
+++ b/tests/ut/ge/graph/manager/session_scope_mem_allocator_unittest.cc
@@ -0,0 +1,75 @@
 /**
 * Copyright 2019-2020 Huawei Technologies Co., Ltd
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

 #include <gtest/gtest.h>
 #include <memory>

 #include "graph/anchor.h"
 #include "graph/attr_value.h"
 #include "graph/debug/ge_attr_define.h"
 #include "graph/utils/graph_utils.h"
 #include "graph/utils/node_utils.h"
 #include "graph/utils/op_desc_utils.h"
 #include "graph/utils/tensor_utils.h"
 #include "omg/omg_inner_types.h"

 #define protected public
 #define private public
 #include "graph/manager/graph_mem_manager.h"
 #undef protected
 #undef private

 using namespace std;
 using namespace testing;
 using namespace ge;
 using domi::GetContext;

 class UtestSessionScopeMemAllocator : public testing::Test {
 protected:
  void SetUp() {}

  void TearDown() { GetContext().out_nodes_map.clear(); }
 };

 TEST_F(UtestSessionScopeMemAllocator, initialize_success) {
  std::vector<rtMemType_t> mem_type;
  mem_type.push_back(RT_MEMORY_HBM);
  EXPECT_EQ(MemManager::Instance().Initialize(mem_type), SUCCESS);
  MemManager::Instance().Finalize();
 }

 TEST_F(UtestSessionScopeMemAllocator, malloc_success) {
  std::vector<rtMemType_t> mem_type;
  mem_type.push_back(RT_MEMORY_HBM);
  EXPECT_EQ(MemManager::Instance().Initialize(mem_type), SUCCESS);
  uint8_t *ptr = MemManager::Instance().SessionScopeMemInstance(RT_MEMORY_HBM).Malloc(1000, 0);
  EXPECT_NE(nullptr, ptr);
  MemManager::Instance().Finalize();
 }

 TEST_F(UtestSessionScopeMemAllocator, free_success) {
  std::vector<rtMemType_t> mem_type;
  mem_type.push_back(RT_MEMORY_HBM);
  EXPECT_EQ(MemManager::Instance().Initialize(mem_type), SUCCESS);
  uint8_t *ptr = MemManager::Instance().SessionScopeMemInstance(RT_MEMORY_HBM).Malloc(100, 0);
  EXPECT_NE(nullptr, ptr);
  ptr = MemManager::Instance().SessionScopeMemInstance(RT_MEMORY_HBM).Malloc(100, 0);
  EXPECT_NE(nullptr, ptr);

  EXPECT_EQ(SUCCESS, MemManager::Instance().SessionScopeMemInstance(RT_MEMORY_HBM).Free(0));
  EXPECT_NE(SUCCESS, MemManager::Instance().SessionScopeMemInstance(RT_MEMORY_HBM).Free(0));
  MemManager::Instance().Finalize();
 }
--- a/tests/ut/ge/graph/passes/variable_op_pass_unittest.cc
+++ b/tests/ut/ge/graph/passes/variable_op_pass_unittest.cc
@@ -35,7 +35,7 @@
 #include "graph/manager/graph_context.h"
 #include "graph/optimize/graph_optimize.h"
 #include "graph/manager/util/variable_accelerate_ctrl.h"
 #include "graph/manager/graph_mem_allocator.h"
 #include "graph/manager/graph_mem_manager.h"
 #include "graph/manager/graph_var_manager.h"
 #include "graph_builder_utils.h"
 #include "cce/dnn.h"