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mindspore2022/mindspore/ccsrc/debug/data_dump/e2e_dump.cc

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  1. /**

  2.  * Copyright 2020-2021 Huawei Technologies Co., Ltd

  3.  *

  4.  * Licensed under the Apache License, Version 2.0 (the "License");

  5.  * you may not use this file except in compliance with the License.

  6.  * You may obtain a copy of the License at

  7.  *

  8.  * http://www.apache.org/licenses/LICENSE-2.0

  9.  *

  10.  * Unless required by applicable law or agreed to in writing, software

  11.  * distributed under the License is distributed on an "AS IS" BASIS,

  12.  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.

  13.  * See the License for the specific language governing permissions and

  14.  * limitations under the License.

  15.  */

  16. 

  17. #include "debug/data_dump/e2e_dump.h"

  18. 

  19. #include <unistd.h>

  20. #include <algorithm>

  21. #include <map>

  22. #include <set>

  23. #include <utility>

  24. #include <vector>

  25. #include "debug/data_dump/dump_json_parser.h"

  26. #include "common/trans.h"

  27. #include "debug/anf_ir_utils.h"

  28. #include "debug/common.h"

  29. #include "backend/session/anf_runtime_algorithm.h"

  30. #include "utils/ms_context.h"

  31. #include "runtime/device/kernel_runtime_manager.h"

  32. #include "utils/config_manager.h"

  33. #include "utils/file_utils.h"

  34. #include "debug/data_dump/tensor_stat_dump.h"

  35. #include "abstract/utils.h"

  36. #ifdef ENABLE_DEBUGGER

  37. #include "debug/debug_services.h"

  38. #include "debug/tensor_load.h"

  39. #include "debug/debugger/debugger.h"

  40. #endif

  41. 

  42. namespace mindspore {

  43. #ifdef ENABLE_D

  44. using ProtoFormat = debugger::dump::OutputFormat;

  45. using ProtoDataType = debugger::dump::OutputDataType;

  46. 

  47. constexpr int kDhaAtomicAddInfoSize = 128;

  48. constexpr int kL2AtomicAddInfoSize = 128;

  49. constexpr int kAiCoreInfoSize = 256;

  50. constexpr int kDhaAtomicAddStatusSize = 256;

  51. constexpr int kL2AtomicAddStatusSize = 256;

  52. constexpr int kUint64Size = sizeof(uint64_t);

  53. const std::set<std::pair<std::string, std::string>> kSuppTransFormatPair = {

  54.   // {device format, host format}

  55.   {kOpFormat_FRAC_Z, kOpFormat_NCHW},      {kOpFormat_FRAC_NZ, kOpFormat_NCHW},

  56.   {kOpFormat_NC1HWC0, kOpFormat_NCHW},     {kOpFormat_C1HWNCoC0, kOpFormat_NCHW},

  57.   {kOpFormat_NC1HWC0_C04, kOpFormat_NCHW}, {kOpFormat_NDC1HWC0, kOpFormat_NCHW},

  58.   {kOpFormat_FRACTAL_Z_3D, kOpFormat_NCHW}};

  59. 

  60. const std::map<ProtoFormat, std::string> kFormatToStringMap = {

  61.   {ProtoFormat::FORMAT_NCHW, kOpFormat_NCHW},

  62.   {ProtoFormat::FORMAT_NHWC, kOpFormat_NHWC},

  63.   {ProtoFormat::FORMAT_ND, kOpFormat_ND},

  64.   {ProtoFormat::FORMAT_NC1HWC0, kOpFormat_NC1HWC0},

  65.   {ProtoFormat::FORMAT_FRACTAL_Z, kOpFormat_FRAC_Z},

  66.   {ProtoFormat::FORMAT_NC1HWC0_C04, kOpFormat_NC1HWC0_C04},

  67.   {ProtoFormat::FORMAT_FRACTAL_Z_C04, kOpFormat_FRACTAL_Z_C04},

  68.   {ProtoFormat::FORMAT_NC1KHKWHWC0, kOpFormat_NC1KHKWHWC0},

  69.   {ProtoFormat::FORMAT_HWCN, kOpFormat_HWCN},

  70.   {ProtoFormat::FORMAT_NDHWC, kOpFormat_NDHWC},

  71.   {ProtoFormat::FORMAT_NCDHW, kOpFormat_NCDHW},

  72.   {ProtoFormat::FORMAT_DHWCN, kOpFormat_DHWCN},

  73.   {ProtoFormat::FORMAT_DHWNC, kOpFormat_DHWNC},

  74.   {ProtoFormat::FORMAT_NDC1HWC0, kOpFormat_NDC1HWC0},

  75.   {ProtoFormat::FORMAT_FRACTAL_Z_3D, kOpFormat_FRACTAL_Z_3D},

  76.   {ProtoFormat::FORMAT_C1HWNCoC0, kOpFormat_C1HWNCoC0},

  77.   {ProtoFormat::FORMAT_FRACTAL_NZ, kOpFormat_FRAC_NZ},

  78.   {ProtoFormat::FORMAT_FRACTAL_ZN_LSTM, kOpFormat_FRACTAL_ZN_LSTM}};

  79. 

  80. const std::map<ProtoDataType, mindspore::TypeId> kDataTypetoMSTypeMap = {

  81.   {ProtoDataType::DT_UNDEFINED, mindspore::TypeId::kTypeUnknown},

  82.   {ProtoDataType::DT_FLOAT, mindspore::TypeId::kNumberTypeFloat32},

  83.   {ProtoDataType::DT_FLOAT16, mindspore::TypeId::kNumberTypeFloat16},

  84.   {ProtoDataType::DT_INT8, mindspore::TypeId::kNumberTypeInt8},

  85.   {ProtoDataType::DT_UINT8, mindspore::TypeId::kNumberTypeUInt8},

  86.   {ProtoDataType::DT_INT16, mindspore::TypeId::kNumberTypeInt16},

  87.   {ProtoDataType::DT_UINT16, mindspore::TypeId::kNumberTypeUInt16},

  88.   {ProtoDataType::DT_INT32, mindspore::TypeId::kNumberTypeInt32},

  89.   {ProtoDataType::DT_INT64, mindspore::TypeId::kNumberTypeInt64},

  90.   {ProtoDataType::DT_UINT32, mindspore::TypeId::kNumberTypeUInt32},

  91.   {ProtoDataType::DT_UINT64, mindspore::TypeId::kNumberTypeUInt64},

  92.   {ProtoDataType::DT_BOOL, mindspore::TypeId::kNumberTypeBool},

  93.   {ProtoDataType::DT_DOUBLE, mindspore::TypeId::kNumberTypeFloat64},

  94.   {ProtoDataType::DT_STRING, mindspore::TypeId::kObjectTypeString}};

  95. #endif

  96. 

  97. bool E2eDump::IsDeviceTargetGPU() {

  98.   auto context = MsContext::GetInstance();

  99.   MS_EXCEPTION_IF_NULL(context);

  100.   return context->get_param<std::string>(MS_CTX_DEVICE_TARGET) == kGPUDevice;

  101. }

  102. 

  103. void E2eDump::DumpGPUMemToFile(const std::string &file_path, const std::string &original_kernel_name,

  104.                                const device::DeviceAddress &addr, const ShapeVector &int_shapes,

  105.                                const TypeId &host_type, const TypeId &device_type, bool trans_flag, size_t slot,

  106.                                const Debugger *debugger) {

  107. #ifdef ENABLE_DEBUGGER

  108.   auto format = kOpFormat_DEFAULT;

  109.   MS_EXCEPTION_IF_NULL(debugger);

  110.   auto ret = debugger->DumpTensorToFile(original_kernel_name, trans_flag, file_path, format, int_shapes, host_type,

  111.                                         device_type, addr.format(), slot);

  112.   if (!ret) {

  113.     MS_LOG(INFO) << "DumpTensorToFile Failed: flag:" << trans_flag << ", path:" << file_path

  114.                  << ", host_format:" << format;

  115.   }

  116. #endif

  117. }

  118. 

  119. void E2eDump::DumpOutput(const session::KernelGraph *graph, const std::string &dump_path, const Debugger *debugger) {

  120.   MS_EXCEPTION_IF_NULL(graph);

  121.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  122.   if (!dump_json_parser.OutputNeedDump()) {

  123.     return;

  124.   }

  125.   MS_LOG(INFO) << "Start e2e dump output";

  126.   bool trans_flag = dump_json_parser.trans_flag();

  127.   const auto &apply_kernels = graph->execution_order();

  128.   for (const auto &node : apply_kernels) {

  129.     MS_EXCEPTION_IF_NULL(node);

  130.     std::string kernel_name = GetKernelNodeName(node);

  131.     if (!dump_json_parser.NeedDump(kernel_name)) {

  132.       continue;

  133.     }

  134.     DumpJsonParser::GetInstance().MatchKernel(kernel_name);

  135.     DumpOutputImpl(node, trans_flag, dump_path, &kernel_name, debugger);

  136.   }

  137. }

  138. 

  139. void E2eDump::DumpOutputSingleNode(const CNodePtr &node, const std::string &dump_path, const Debugger *debugger) {

  140.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  141.   if (!dump_json_parser.OutputNeedDump()) {

  142.     return;

  143.   }

  144.   bool trans_flag = dump_json_parser.trans_flag();

  145.   MS_EXCEPTION_IF_NULL(node);

  146.   std::string kernel_name = GetKernelNodeName(node);

  147.   if (!dump_json_parser.NeedDump(kernel_name)) {

  148.     return;

  149.   }

  150.   DumpJsonParser::GetInstance().MatchKernel(kernel_name);

  151.   DumpOutputImpl(node, trans_flag, dump_path, &kernel_name, debugger);

  152. }

  153. 

  154. void E2eDump::DumpOutputImpl(const CNodePtr &node, bool trans_flag, const std::string &dump_path,

  155.                              std::string *kernel_name, const Debugger *debugger) {

  156.   MS_EXCEPTION_IF_NULL(node);

  157.   GetFileKernelName(NOT_NULL(kernel_name));

  158.   auto output_size = AnfAlgo::GetOutputTensorNum(node);

  159.   for (size_t j = 0; j < output_size; ++j) {

  160.     if (!AnfAlgo::OutputAddrExist(node, j)) {

  161.       continue;

  162.     }

  163.     auto addr = AnfAlgo::GetOutputAddr(node, j);

  164.     MS_EXCEPTION_IF_NULL(addr);

  165.     ShapeVector int_shapes;

  166.     GetDumpIntShape(node, j, NOT_NULL(&int_shapes), trans_flag);

  167.     auto type = AnfAlgo::GetOutputInferDataType(node, j);

  168.     auto device_type = AnfAlgo::GetOutputDeviceDataType(node, j);

  169.     std::string op_type = AnfAlgo::GetCNodeName(node);

  170.     std::string op_name = GetOpNameWithoutScope(*kernel_name);

  171.     uint32_t task_id = 0;

  172.     uint32_t stream_id = 0;

  173.     uint64_t timestamp = GetTimeStamp();

  174.     std::string file_path = dump_path + '/' + op_type + '.' + op_name + '.' + std::to_string(task_id) + '.' +

  175.                             std::to_string(stream_id) + '.' + std::to_string(timestamp) + ".output." +

  176.                             std::to_string(j);

  177.     if (IsDeviceTargetGPU()) {

  178.       if (DumpJsonParser::GetInstance().IsStatisticDump()) {

  179.         TensorStatDump stat_dump(op_type, op_name, task_id, stream_id, timestamp, false, j, j);

  180.         stat_dump.DumpTensorStatsToFile(GetKernelNodeName(node), dump_path, debugger);

  181.       }

  182.       if (DumpJsonParser::GetInstance().IsTensorDump()) {

  183.         DumpGPUMemToFile(file_path, GetKernelNodeName(node), *addr, int_shapes, type, device_type, trans_flag, j,

  184.                          debugger);

  185.       }

  186.     } else {

  187.       DumpMemToFile(file_path, *addr, int_shapes, type, trans_flag);

  188.     }

  189.   }

  190. }

  191. 

  192. void E2eDump::DumpInput(const session::KernelGraph *graph, const std::string &dump_path, const Debugger *debugger) {

  193.   MS_EXCEPTION_IF_NULL(graph);

  194.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  195.   if (!dump_json_parser.InputNeedDump()) {

  196.     return;

  197.   }

  198.   MS_LOG(INFO) << "Start e2e dump input";

  199.   bool trans_flag = dump_json_parser.trans_flag();

  200.   const auto &apply_kernels = graph->execution_order();

  201.   for (const auto &node : apply_kernels) {

  202.     MS_EXCEPTION_IF_NULL(node);

  203.     std::string kernel_name = GetKernelNodeName(node);

  204.     if (!dump_json_parser.NeedDump(kernel_name)) {

  205.       continue;

  206.     }

  207.     DumpJsonParser::GetInstance().MatchKernel(kernel_name);

  208.     DumpInputImpl(node, trans_flag, dump_path, &kernel_name, debugger);

  209.   }

  210. }

  211. 

  212. void E2eDump::DumpInputSingleNode(const CNodePtr &node, const std::string &dump_path, const Debugger *debugger) {

  213.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  214.   if (!dump_json_parser.InputNeedDump()) {

  215.     return;

  216.   }

  217.   bool trans_flag = dump_json_parser.trans_flag();

  218.   MS_EXCEPTION_IF_NULL(node);

  219.   std::string kernel_name = GetKernelNodeName(node);

  220.   if (!dump_json_parser.NeedDump(kernel_name)) {

  221.     return;

  222.   }

  223.   DumpJsonParser::GetInstance().MatchKernel(kernel_name);

  224.   DumpInputImpl(node, trans_flag, dump_path, &kernel_name, debugger);

  225. }

  226. 

  227. void E2eDump::DumpInputImpl(const CNodePtr &node, bool trans_flag, const std::string &dump_path,

  228.                             std::string *kernel_name, const Debugger *debugger) {

  229.   MS_EXCEPTION_IF_NULL(node);

  230.   GetFileKernelName(NOT_NULL(kernel_name));

  231.   auto input_size = AnfAlgo::GetInputTensorNum(node);

  232.   for (size_t j = 0; j < input_size; ++j) {

  233.     auto kernel_with_index = AnfAlgo::GetPrevNodeOutput(node, j);

  234.     auto input = kernel_with_index.first;

  235.     auto index = kernel_with_index.second;

  236.     if (!AnfAlgo::OutputAddrExist(input, index)) {

  237.       continue;

  238.     }

  239.     auto addr = AnfAlgo::GetOutputAddr(input, index);

  240.     MS_EXCEPTION_IF_NULL(addr);

  241. 

  242.     std::string tensor_name = GetKernelNodeName(node);

  243.     size_t slot = j;

  244.     if (IsDeviceTargetGPU()) {

  245.       auto input_kernel = node->input(j + 1);

  246.       std::string input_kernel_name = GetKernelNodeName(input_kernel);

  247.       tensor_name = input_kernel_name;

  248.       slot = 0;

  249.     }

  250.     ShapeVector int_shapes;

  251.     GetDumpIntShape(input, index, NOT_NULL(&int_shapes), trans_flag);

  252.     auto type = AnfAlgo::GetOutputInferDataType(input, index);

  253.     auto device_type = AnfAlgo::GetOutputDeviceDataType(input, index);

  254.     std::string op_type = AnfAlgo::GetCNodeName(node);

  255.     std::string op_name = GetOpNameWithoutScope(*kernel_name);

  256.     uint64_t timestamp = GetTimeStamp();

  257.     uint32_t task_id = 0;

  258.     uint32_t stream_id = 0;

  259.     std::string file_path = dump_path + '/' + op_type + '.' + op_name + '.' + std::to_string(task_id) + '.' +

  260.                             std::to_string(stream_id) + '.' + std::to_string(timestamp) + ".input." + std::to_string(j);

  261.     MS_EXCEPTION_IF_NULL(addr);

  262.     if (IsDeviceTargetGPU()) {

  263.       if (DumpJsonParser::GetInstance().IsStatisticDump()) {

  264.         TensorStatDump stat_dump(op_type, op_name, task_id, stream_id, timestamp, true, j, slot);

  265.         stat_dump.DumpTensorStatsToFile(tensor_name, dump_path, debugger);

  266.       }

  267.       if (DumpJsonParser::GetInstance().IsTensorDump()) {

  268.         DumpGPUMemToFile(file_path, tensor_name, *addr, int_shapes, type, device_type, trans_flag, slot, debugger);

  269.       }

  270.     } else {

  271.       DumpMemToFile(file_path, *addr, int_shapes, type, trans_flag);

  272.     }

  273.   }

  274. }

  275. 

  276. void E2eDump::DumpSingleAnfNode(const AnfNodePtr &anf_node, const size_t output_index, const std::string &dump_path,

  277.                                 bool trans_flag, std::map<std::string, size_t> *const_map, const Debugger *debugger) {

  278.   MS_EXCEPTION_IF_NULL(anf_node);

  279.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  280.   if ((!anf_node->isa<Parameter>() && !anf_node->isa<ValueNode>()) || IsValueNode<StringImm>(anf_node)) {

  281.     return;

  282.   }

  283.   std::string node_name = GetKernelNodeName(anf_node);

  284.   std::string dump_name = node_name;

  285.   if (anf_node->isa<ValueNode>()) {

  286.     MS_EXCEPTION_IF_NULL(const_map);

  287.     auto iter = const_map->find(node_name);

  288.     if (iter == const_map->end()) {

  289.       return;

  290.     }

  291.     dump_name = std::string("cst") + std::to_string(iter->second);

  292.   }

  293. 

  294.   if (!dump_json_parser.NeedDump(node_name)) {

  295.     return;

  296.   }

  297.   DumpJsonParser::GetInstance().MatchKernel(node_name);

  298.   GetFileKernelName(NOT_NULL(&node_name));

  299.   // check if output address exists, if not, return;

  300.   if (!AnfAlgo::OutputAddrExist(anf_node, output_index)) {

  301.     return;

  302.   }

  303.   auto addr = AnfAlgo::GetOutputAddr(anf_node, output_index);

  304.   MS_EXCEPTION_IF_NULL(addr);

  305.   ShapeVector int_shapes;

  306.   GetDumpIntShape(anf_node, output_index, NOT_NULL(&int_shapes), trans_flag);

  307.   auto type = AnfAlgo::GetOutputInferDataType(anf_node, output_index);

  308.   auto device_type = AnfAlgo::GetOutputDeviceDataType(anf_node, output_index);

  309.   uint64_t timestamp = GetTimeStamp();

  310.   uint32_t task_id = 0;

  311.   uint32_t stream_id = 0;

  312.   std::string file_path = dump_path + "/Parameter." + dump_name + '.' + std::to_string(task_id) + '.' +

  313.                           std::to_string(stream_id) + '.' + std::to_string(timestamp) + ".output.0";

  314.   if (IsDeviceTargetGPU()) {

  315.     if (dump_json_parser.IsStatisticDump()) {

  316.       TensorStatDump stat_dump("Parameter", dump_name, task_id, stream_id, timestamp, false, 0, 0);

  317.       stat_dump.DumpTensorStatsToFile(node_name, dump_path, debugger);

  318.     }

  319.     if (dump_json_parser.IsTensorDump()) {

  320.       DumpGPUMemToFile(file_path, node_name, *addr, int_shapes, type, device_type, trans_flag, 0, debugger);

  321.     }

  322.   } else {

  323.     DumpMemToFile(file_path, *addr, int_shapes, type, trans_flag);

  324.   }

  325. }

  326. 

  327. void E2eDump::DumpParametersAndConst(const session::KernelGraph *graph, const std::string &dump_path,

  328.                                      const Debugger *debugger) {

  329.   MS_EXCEPTION_IF_NULL(graph);

  330.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  331.   if (!dump_json_parser.OutputNeedDump()) {

  332.     return;

  333.   }

  334.   MS_LOG(INFO) << "Start e2e dump parameters and Const values";

  335.   bool trans_flag = dump_json_parser.trans_flag();

  336.   std::map<std::string, size_t> const_map;

  337.   GetConstantId(graph, &const_map);

  338. 

  339.   // dump parameters

  340.   const auto &parameters = graph->inputs();

  341.   for (auto &item : parameters) {

  342.     DumpSingleAnfNode(item, PARAMETER_OUTPUT_INDEX, dump_path, trans_flag, &const_map, debugger);

  343.   }

  344.   // dump const values

  345.   auto value_nodes = graph->graph_value_nodes();

  346.   for (const auto &value_node : value_nodes) {

  347.     DumpSingleAnfNode(value_node, VALUE_NODE_OUTPUT_INDEX, dump_path, trans_flag, &const_map, debugger);

  348.   }

  349. }

  350. 

  351. void E2eDump::UpdateIterDumpSetup(const session::KernelGraph *graph, bool sink_mode) {

  352.   uint32_t graph_id = graph->graph_id();

  353.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  354.   if (IsDeviceTargetGPU()) {

  355.     if (starting_graph_id == INT32_MAX) {

  356.       starting_graph_id = graph_id;

  357.     } else if (starting_graph_id == graph_id && !MsContext::GetInstance()->get_param<bool>(MS_CTX_ENABLE_MINDRT)) {

  358.       // Update dump iter for mindrt runtime is done using UpdateIterGPUDump().

  359.       // Update dump iter for GPU old runtime.

  360.       dump_json_parser.UpdateDumpIter();

  361.     }

  362.     return;

  363.   }

  364.   // If device target is Ascend

  365.   if (sink_mode && graph->IsDatasetGraph()) {

  366.     MS_LOG(INFO) << "No need to update iteration for dataset graph.";

  367.     return;

  368.   }

  369. 

  370.   // In multi network scripts, dump iter is equal to the number of networks that have been executed so far.

  371.   dump_json_parser.UpdateDumpIter();

  372. }

  373. 

  374. void E2eDump::DumpSetup(const session::KernelGraph *graph) {

  375.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  376.   bool sink_mode = (ConfigManager::GetInstance().dataset_mode() || E2eDump::isDatasetGraph(graph));

  377. 

  378.   if (dump_json_parser.async_dump_enabled() || dump_json_parser.e2e_dump_enabled()) {

  379.     UpdateIterDumpSetup(graph, sink_mode);

  380.   }

  381. }

  382. 

  383. void E2eDump::UpdateIterGPUDump() { DumpJsonParser::GetInstance().UpdateDumpIter(); }

  384. 

  385. void E2eDump::DumpRunIter(const KernelGraphPtr &graph, uint32_t rank_id) {

  386.   auto &json_parser = DumpJsonParser::GetInstance();

  387.   if (!(json_parser.async_dump_enabled() || json_parser.e2e_dump_enabled())) {

  388.     return;

  389.   }

  390.   bool sink_mode = (ConfigManager::GetInstance().dataset_mode() || graph->IsDatasetGraph());

  391.   auto iter_num = SizeToInt(LongToSize(ConfigManager::GetInstance().iter_num()));

  392.   if (graph->IsDatasetGraph()) {

  393.     MS_LOG(INFO) << "graph: " << graph->graph_id() << " is dataset graph, not creating graph history file.";

  394.     return;

  395.   }

  396.   std::string execution_order_path = json_parser.path() + "/rank_" + std::to_string(rank_id) + "/execution_order/";

  397.   std::string file_name_to_check =

  398.     execution_order_path + "/ms_global_execution_order_graph_" + std::to_string(graph->graph_id()) + ".csv";

  399.   auto real_path = Common::CreatePrefixPath(file_name_to_check);

  400.   if (!real_path.has_value()) {

  401.     MS_LOG(WARNING) << "Check file path: " << file_name_to_check << " failed.";

  402.     return;

  403.   }

  404.   std::string file_name = real_path.value();

  405.   ChangeFileMode(file_name, S_IWUSR);

  406.   std::ofstream fout(file_name, std::ofstream::app);

  407.   if (!fout.is_open()) {

  408.     MS_LOG(WARNING) << "Open file for saving graph global execution order failed.";

  409.     return;

  410.   }

  411.   if (sink_mode && json_parser.async_dump_enabled()) {

  412.     // for async dump when sink_mode = true, cur_dump_iter() = current_epoch

  413.     // dump history for all iterations in the epoch

  414.     for (int i = 0; i < iter_num; i++) {

  415.       fout << std::to_string(json_parser.cur_dump_iter() * iter_num + i) + "\n";

  416.     }

  417.   } else {

  418.     fout << std::to_string(json_parser.cur_dump_iter()) + "\n";

  419.   }

  420.   fout.close();

  421.   ChangeFileMode(file_name, S_IRUSR);

  422. }

  423. 

  424. void E2eDump::DumpData(const session::KernelGraph *graph, uint32_t rank_id, const Debugger *debugger) {

  425.   MS_EXCEPTION_IF_NULL(graph);

  426.   bool success = false;

  427.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  428.   uint32_t graph_id = graph->graph_id();

  429. 

  430.   if (dump_json_parser.GetIterDumpFlag()) {

  431.     MS_LOG(INFO) << "Start e2e dump. Current iteration is " << dump_json_parser.cur_dump_iter();

  432.     MS_LOG(INFO) << "Current graph id is " << graph_id;

  433.     std::string dump_path = GenerateDumpPath(graph_id, rank_id);

  434. 

  435.     if (dump_json_parser.IsStatisticDump()) {

  436.       TensorStatDump::OpenStatisticsFile(dump_path);

  437.     }

  438.     DumpInput(graph, dump_path, debugger);

  439.     DumpOutput(graph, dump_path, debugger);

  440.     DumpParametersAndConst(graph, dump_path, debugger);

  441.     if (dump_json_parser.IsStatisticDump()) {

  442.       CsvWriter::GetInstance().CloseFile();

  443.     }

  444.     success = true;

  445.   }

  446. 

  447.   if (success) {

  448.     MS_LOG(DEBUG) << "E2eDump Dump Data completed!";

  449.   } else {

  450.     MS_LOG(DEBUG) << "E2eDump Dump has not occurred!";

  451.   }

  452. }

  453. 

  454. bool E2eDump::DumpSingleNodeData(const CNodePtr &node, uint32_t graph_id, uint32_t rank_id, const Debugger *debugger) {

  455.   bool success = false;

  456.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  457.   if (dump_json_parser.GetIterDumpFlag()) {

  458.     std::string dump_path = GenerateDumpPath(graph_id, rank_id);

  459.     DumpInputSingleNode(node, dump_path, debugger);

  460.     DumpOutputSingleNode(node, dump_path, debugger);

  461.     success = true;

  462.   }

  463.   return success;

  464. }

  465. 

  466. bool E2eDump::DumpParametersAndConstData(const session::KernelGraph *graph, uint32_t rank_id,

  467.                                          const Debugger *debugger) {

  468.   bool success = false;

  469.   uint32_t graph_id = graph->graph_id();

  470.   auto &dump_json_parser = DumpJsonParser::GetInstance();

  471.   if (dump_json_parser.GetIterDumpFlag()) {

  472.     MS_LOG(INFO) << "DumpParametersAndConst. Current iteration is " << dump_json_parser.cur_dump_iter();

  473.     MS_LOG(INFO) << "Current graph id is " << graph_id;

  474.     std::string dump_path = GenerateDumpPath(graph_id, rank_id);

  475.     DumpParametersAndConst(graph, dump_path, debugger);

  476.     success = true;

  477.   }

  478.   return success;

  479. }

  480. bool E2eDump::isDatasetGraph(const session::KernelGraph *graph) {

  481.   // check if there is GetNext or InitDataSetQueue node

  482.   const auto &nodes = graph->execution_order();

  483.   for (const auto &node : nodes) {

  484.     auto node_name = AnfAlgo::GetCNodeName(node);

  485.     if (node_name == prim::kPrimGetNext->name() || node_name == prim::kPrimInitDataSetQueue->name()) {

  486.       return true;

  487.     }

  488.   }

  489.   return false;

  490. }

  491. 

  492. bool E2eDump::DumpDirExists(const std::string &dump_path) {

  493.   DIR *dir = opendir(dump_path.c_str());

  494.   if (dir != nullptr) {

  495.     MS_LOG(INFO) << "Dump dir " << dump_path << " exists";

  496.     if (closedir(dir) == -1) {

  497.       MS_LOG(WARNING) << "Dump dir " << dump_path << " close failed!";

  498.     }

  499.     return true;

  500.   }

  501.   return false;

  502. }

  503. 

  504. #ifdef ENABLE_D

  505. void E2eDump::DumpTensorToFile(const std::string &dump_path, const debugger::dump::DumpData &dump_data,

  506.                                char *data_ptr) {

  507.   // dump input tensors

  508.   std::vector<debugger::dump::OpInput> input_tensors(dump_data.input().begin(), dump_data.input().end());

  509.   uint64_t offset = 0;

  510.   std::string in_path = dump_path + ".input.";

  511.   for (uint32_t slot = 0; slot < input_tensors.size(); slot++) {

  512.     auto in_tensor = input_tensors[slot];

  513.     std::string in_slot_path = in_path + std::to_string(slot) + ".";

  514.     auto succ = ConvertFormatForTensorAndDump(in_slot_path, in_tensor, data_ptr + offset);

  515.     if (!succ) {

  516.       MS_LOG(INFO) << "Failed to convert format for tensor " << in_slot_path;

  517.     }

  518.     offset += in_tensor.size();

  519.   }

  520. 

  521.   // dump output tensors

  522.   std::vector<debugger::dump::OpOutput> output_tensors(dump_data.output().begin(), dump_data.output().end());

  523.   std::string out_path = dump_path + ".output.";

  524.   for (uint32_t slot = 0; slot < output_tensors.size(); slot++) {

  525.     auto out_tensor = output_tensors[slot];

  526.     std::string out_slot_path = out_path + std::to_string(slot) + ".";

  527.     auto succ = ConvertFormatForTensorAndDump(out_slot_path, out_tensor, data_ptr + offset);

  528.     if (!succ) {

  529.       MS_LOG(INFO) << "Failed to convert format for tensor " << out_slot_path;

  530.     }

  531.     offset += out_tensor.size();

  532.   }

  533. }

  534. 

  535. template <typename T>

  536. bool E2eDump::ConvertFormatForTensorAndDump(std::string dump_path, const T &tensor, char *data_ptr) {

  537.   // get format

  538.   auto iter_fmt = kFormatToStringMap.find(tensor.format());

  539.   if (iter_fmt == kFormatToStringMap.end()) {

  540.     MS_LOG(INFO) << "Unsupported tensor format " << iter_fmt->second << " for tensor " << dump_path;

  541.     return false;

  542.   }

  543.   std::string device_format = iter_fmt->second;

  544.   // get data type

  545.   auto iter_dtype = kDataTypetoMSTypeMap.find(tensor.data_type());

  546.   if (iter_dtype == kDataTypetoMSTypeMap.end()) {

  547.     MS_LOG(INFO) << "Unsupported tensor type " << iter_dtype->second << " for tensor " << dump_path;

  548.     return false;

  549.   }

  550.   auto src_type = iter_dtype->second;

  551.   // get host shape

  552.   std::vector<size_t> device_shape;

  553.   (void)std::copy(tensor.shape().dim().begin(), tensor.shape().dim().end(), std::back_inserter(device_shape));

  554.   std::vector<size_t> host_shape;

  555.   (void)std::copy(tensor.original_shape().dim().begin(), tensor.original_shape().dim().end(),

  556.                   std::back_inserter(host_shape));

  557.   ShapeVector shape_to;

  558.   (void)std::transform(host_shape.begin(), host_shape.end(), std::back_inserter(shape_to), SizeToLong);

  559.   size_t data_size = (size_t)tensor.size();

  560. 

  561.   bool trans_success = false;

  562.   auto trans_buf = std::vector<uint8_t>(data_size);

  563.   // convert format to host format. It can be either NCHW or ND (non 4-dimemsions).

  564.   const uint8_t kNumFourDim = 4;

  565.   std::string host_format;

  566.   if (host_shape.size() == kNumFourDim) {

  567.     host_format = kOpFormat_NCHW;

  568.   } else {

  569.     host_format = kOpFormat_ND;

  570.   }

  571.   if (device_format != host_format) {

  572.     auto iter = kSuppTransFormatPair.find(std::make_pair(device_format, host_format));

  573.     if (iter == kSuppTransFormatPair.end()) {

  574.       MS_LOG(INFO) << "Do not support convert from format " << device_format << " to " << host_format << " for tensor "

  575.                    << dump_path;

  576.     } else {

  577.       const trans::FormatArgs format_args{data_ptr,   data_size,    host_format, device_format,

  578.                                           host_shape, device_shape, src_type};

  579.       auto group = tensor.sub_format() > 1 ? tensor.sub_format() : 1;

  580.       trans_success = trans::TransFormatFromDeviceToHost(format_args, trans_buf.data(), group);

  581.       if (!trans_success) {

  582.         MS_LOG(ERROR) << "Trans format failed.";

  583.       }

  584.     }

  585.   }

  586.   // dump tensor data into npy file

  587.   bool dump_success = false;

  588.   if (trans_success) {

  589.     dump_path += host_format;

  590.     dump_success = DumpJsonParser::DumpToFile(dump_path, trans_buf.data(), data_size, shape_to, src_type);

  591.   } else {

  592.     dump_path += device_format;

  593.     dump_success = DumpJsonParser::DumpToFile(dump_path, data_ptr, data_size, shape_to, src_type);

  594.   }

  595.   return dump_success;

  596. }

  597. 

  598. uint64_t UnpackUint64Value(char *ptr) {

  599. #if defined(__APPLE__)

  600.   return *reinterpret_cast<const uint64_t *>(ptr);

  601. #else

  602.   return le16toh(*reinterpret_cast<const uint64_t *>(ptr));

  603. #endif

  604. }

  605. 

  606. std::string IntToHexString(const uint64_t value) {

  607.   std::stringstream ss;

  608.   ss << "0x" << std::hex << value;

  609.   return ss.str();

  610. }

  611. 

  612. nlohmann::json E2eDump::ParseOverflowInfo(char *data_ptr) {

  613.   uint32_t index = 0;

  614.   uint64_t model_id = UnpackUint64Value(data_ptr + index);

  615.   index += kUint64Size;

  616.   uint64_t stream_id = UnpackUint64Value(data_ptr + index);

  617.   index += kUint64Size;

  618.   uint64_t task_id = UnpackUint64Value(data_ptr + index);

  619.   index += kUint64Size;

  620.   uint64_t task_type = UnpackUint64Value(data_ptr + index);

  621.   index += kUint64Size;

  622.   uint64_t pc_start = UnpackUint64Value(data_ptr + index);

  623.   index += kUint64Size;

  624.   uint64_t para_base = UnpackUint64Value(data_ptr + index);

  625. 

  626.   nlohmann::json overflow_info;

  627.   overflow_info["model_id"] = model_id;

  628.   overflow_info["stream_id"] = stream_id;

  629.   overflow_info["task_id"] = task_id;

  630.   overflow_info["task_type"] = task_type;

  631.   overflow_info["pc_start"] = IntToHexString(pc_start);

  632.   overflow_info["para_base"] = IntToHexString(para_base);

  633.   return overflow_info;

  634. }

  635. 

  636. void E2eDump::DumpOpDebugToFile(const std::string &dump_path, const debugger::dump::DumpData &dump_data,

  637.                                 char *data_ptr) {

  638.   std::string out_path = dump_path + ".output.";

  639.   std::vector<debugger::dump::OpOutput> op_debug(dump_data.output().begin(), dump_data.output().end());

  640.   for (uint32_t slot = 0; slot < op_debug.size(); slot++) {

  641.     uint32_t index = 0;

  642.     // parse DHA Atomic Add info

  643.     nlohmann::json dha_atomic_add_info = ParseOverflowInfo(data_ptr + index);

  644.     index += kDhaAtomicAddInfoSize;

  645.     // parse L2 Atomic Add info

  646.     nlohmann::json l2_atomic_add_info = ParseOverflowInfo(data_ptr + index);

  647.     index += kL2AtomicAddInfoSize;

  648.     // parse AICore info

  649.     nlohmann::json ai_core_info = ParseOverflowInfo(data_ptr + index);

  650.     index += kAiCoreInfoSize;

  651.     // parse DHA Atomic Add status

  652.     dha_atomic_add_info["status"] = UnpackUint64Value(data_ptr + index);

  653.     index += kDhaAtomicAddStatusSize;

  654.     // parse L2 Atomic Add status

  655.     l2_atomic_add_info["status"] = UnpackUint64Value(data_ptr + index);

  656.     index += kL2AtomicAddStatusSize;

  657.     // parse AICore status

  658.     uint64_t kernel_code = UnpackUint64Value(data_ptr + index);

  659.     index += kUint64Size;

  660.     uint64_t block_idx = UnpackUint64Value(data_ptr + index);

  661.     index += kUint64Size;

  662.     uint64_t status = UnpackUint64Value(data_ptr + index);

  663.     ai_core_info["kernel_code"] = IntToHexString(kernel_code);

  664.     ai_core_info["block_idx"] = block_idx;

  665.     ai_core_info["status"] = status;

  666. 

  667.     nlohmann::json opdebug_data;

  668.     opdebug_data["DHA Atomic Add"] = dha_atomic_add_info;

  669.     opdebug_data["L2 Atomic Add"] = l2_atomic_add_info;

  670.     opdebug_data["AI Core"] = ai_core_info;

  671. 

  672.     // save json to file

  673.     DumpToFile(out_path + std::to_string(slot) + ".json", opdebug_data.dump());

  674.   }

  675. }

  676. #endif  // ENABLE_D

  677. }  // namespace mindspore