libprofile/profile/profile_test_helper.h - LeafOS-Project/android_art - Gitiles

 /*
  * Copyright (C) 2021 The Android Open Source Project
  *
  * 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 ART_LIBPROFILE_PROFILE_PROFILE_TEST_HELPER_H_
 #define ART_LIBPROFILE_PROFILE_PROFILE_TEST_HELPER_H_

 #include <memory>
 #include <vector>

 #include "dex/test_dex_file_builder.h"
 #include "profile/profile_compilation_info.h"

 namespace art {

 class ProfileTestHelper {
  public:
   ProfileTestHelper() = default;

   using Hotness = ProfileCompilationInfo::MethodHotness;
   using ProfileInlineCache = ProfileMethodInfo::ProfileInlineCache;
   using ProfileSampleAnnotation = ProfileCompilationInfo::ProfileSampleAnnotation;
   using ProfileIndexType = ProfileCompilationInfo::ProfileIndexType;

   static bool AddMethod(
       ProfileCompilationInfo* info,
       const DexFile* dex,
       uint16_t method_idx,
       const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
     return AddMethod(info, dex, method_idx, Hotness::kFlagHot, annotation);
   }

   static bool AddMethod(
       ProfileCompilationInfo* info,
       const DexFile* dex,
       uint16_t method_idx,
       Hotness::Flag flags,
       const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
     return info->AddMethod(
         ProfileMethodInfo(MethodReference(dex, method_idx)), flags, annotation);
   }

   static bool AddMethod(
       ProfileCompilationInfo* info,
       const DexFile* dex,
       uint16_t method_idx,
       const std::vector<ProfileInlineCache>& inline_caches,
       const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
     return AddMethod(info, dex, method_idx, inline_caches, Hotness::kFlagHot, annotation);
   }

   static bool AddMethod(
       ProfileCompilationInfo* info,
       const DexFile* dex,
       uint16_t method_idx,
       const std::vector<ProfileInlineCache>& inline_caches,
       Hotness::Flag flags,
       const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
     return info->AddMethod(
         ProfileMethodInfo(MethodReference(dex, method_idx), inline_caches), flags, annotation);
   }

   static bool AddClass(ProfileCompilationInfo* info,
                        const DexFile* dex,
                        dex::TypeIndex type_index,
                        const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
     return info->AddClass(*dex, type_index, annotation);
   }

   static bool ProfileIndexMatchesDexFile(const ProfileCompilationInfo& info,
                                          ProfileIndexType profile_index,
                                          const DexFile* dex_file) {
     DCHECK(dex_file != nullptr);
     std::array<const DexFile*, 1u> dex_files{dex_file};
     return dex_file == info.FindDexFileForProfileIndex(profile_index, dex_files);
   }

   // Compare different representations of inline caches for equality.
   static bool EqualInlineCaches(const std::vector<ProfileMethodInfo::ProfileInlineCache>& expected,
                                 const DexFile* dex_file,
                                 const ProfileCompilationInfo::MethodHotness& actual_hotness,
                                 const ProfileCompilationInfo& info) {
     CHECK(actual_hotness.IsHot());
     CHECK(actual_hotness.GetInlineCacheMap() != nullptr);
     const ProfileCompilationInfo::InlineCacheMap& actual = *actual_hotness.GetInlineCacheMap();
     if (expected.size() != actual.size()) {
       return false;
     }
     // The `expected` data should be sorted by dex pc.
     CHECK(std::is_sorted(expected.begin(),
                          expected.end(),
                          [](auto&& lhs, auto&& rhs) { return lhs.dex_pc < rhs.dex_pc; }));
     // The `actual` data is a map sorted by dex pc, so we can just iterate over both.
     auto expected_it = expected.begin();
     for (auto it = actual.begin(), end = actual.end(); it != end; ++it, ++expected_it) {
       uint32_t dex_pc = it->first;
       const ProfileCompilationInfo::DexPcData& dex_pc_data = it->second;
       if (dex_pc != expected_it->dex_pc) {
         return false;
       }
       if (dex_pc_data.is_missing_types != expected_it->is_missing_types) {
         return false;
       } else if (dex_pc_data.is_missing_types) {
         continue;  // The classes do not matter if we're missing some types.
       }
       // The `expected_it->is_megamorphic` is not initialized. Check the number of classes.
       bool expected_is_megamorphic =
           (expected_it->classes.size() >= ProfileCompilationInfo::kIndividualInlineCacheSize);
       if (dex_pc_data.is_megamorphic != expected_is_megamorphic) {
         return false;
       } else if (dex_pc_data.is_megamorphic) {
         continue;  // The classes do not matter if the inline cache is megamorphic.
       }
       if (dex_pc_data.classes.size() != expected_it->classes.size()) {
         return false;
       }
       for (dex::TypeIndex type_index : dex_pc_data.classes) {
         if (std::none_of(expected_it->classes.begin(),
                          expected_it->classes.end(),
                          [&](const TypeReference& type_ref) {
                            if (type_ref.dex_file == dex_file) {
                              return type_index == type_ref.TypeIndex();
                            } else {
                              const char* expected_descriptor =
                                  type_ref.dex_file->StringByTypeIdx(type_ref.TypeIndex());
                              const char* descriptor = info.GetTypeDescriptor(dex_file, type_index);
                              return strcmp(expected_descriptor, descriptor) == 0;
                            }
                          })) {
           return false;
         }
       }
     }
     return true;
   }

  protected:
   static constexpr size_t kNumSharedTypes = 10u;

   const DexFile* BuildDex(const std::string& location,
                           uint32_t location_checksum,
                           const std::string& class_descriptor,
                           size_t num_method_ids,
                           size_t num_class_ids = kNumSharedTypes + 1u) {
     TestDexFileBuilder builder;
     builder.AddType(class_descriptor);
     CHECK_NE(num_class_ids, 0u);
     size_t num_shared_ids = std::min(num_class_ids - 1u, kNumSharedTypes);
     for (size_t shared_type_index = 0; shared_type_index != num_shared_ids; ++shared_type_index) {
       builder.AddType("LSharedType" + std::to_string(shared_type_index) + ";");
     }
     for (size_t i = 1u + num_shared_ids; i < num_class_ids; ++i) {
       builder.AddType("LFiller" + std::to_string(i) + ";");
     }
     for (size_t method_index = 0; method_index != num_method_ids; ++method_index) {
       // Some tests add the maximum number of methods (`num_method_ids` is 2^16) and we
       // do not want to waste memory with that many unique name strings (with identical
       // proto id). So create up to num_shared_ids^2 proto ids and only
       // num_method_ids/num_shared_ids^2 names.
       size_t return_type_index = method_index % num_shared_ids;
       size_t arg_type_index = (method_index / num_shared_ids) % num_shared_ids;
       size_t method_name_index = (method_index / num_shared_ids) / num_shared_ids;
       std::string return_type = "LSharedType" + std::to_string(return_type_index) + ";";
       std::string arg_type = "LSharedType" + std::to_string(arg_type_index) + ";";
       std::string signature = ART_FORMAT("({}){}", arg_type, return_type);
       builder.AddMethod(class_descriptor, signature, "m" + std::to_string(method_name_index));
     }
     storage.push_back(builder.Build(location, location_checksum));
     return storage.back().get();
   }

   std::vector<std::unique_ptr<const DexFile>> storage;
 };

 }  // namespace art

 #endif  // ART_LIBPROFILE_PROFILE_PROFILE_TEST_HELPER_H_
	/*
	* Copyright (C) 2021 The Android Open Source Project
	*
	* 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 ART_LIBPROFILE_PROFILE_PROFILE_TEST_HELPER_H_
	#define ART_LIBPROFILE_PROFILE_PROFILE_TEST_HELPER_H_

	#include <memory>
	#include <vector>

	#include "dex/test_dex_file_builder.h"
	#include "profile/profile_compilation_info.h"

	namespace art {

	class ProfileTestHelper {
	public:
	ProfileTestHelper() = default;

	using Hotness = ProfileCompilationInfo::MethodHotness;
	using ProfileInlineCache = ProfileMethodInfo::ProfileInlineCache;
	using ProfileSampleAnnotation = ProfileCompilationInfo::ProfileSampleAnnotation;
	using ProfileIndexType = ProfileCompilationInfo::ProfileIndexType;

	static bool AddMethod(
	ProfileCompilationInfo* info,
	const DexFile* dex,
	uint16_t method_idx,
	const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
	return AddMethod(info, dex, method_idx, Hotness::kFlagHot, annotation);
	}

	static bool AddMethod(
	ProfileCompilationInfo* info,
	const DexFile* dex,
	uint16_t method_idx,
	Hotness::Flag flags,
	const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
	return info->AddMethod(
	ProfileMethodInfo(MethodReference(dex, method_idx)), flags, annotation);
	}

	static bool AddMethod(
	ProfileCompilationInfo* info,
	const DexFile* dex,
	uint16_t method_idx,
	const std::vector<ProfileInlineCache>& inline_caches,
	const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
	return AddMethod(info, dex, method_idx, inline_caches, Hotness::kFlagHot, annotation);
	}

	static bool AddMethod(
	ProfileCompilationInfo* info,
	const DexFile* dex,
	uint16_t method_idx,
	const std::vector<ProfileInlineCache>& inline_caches,
	Hotness::Flag flags,
	const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
	return info->AddMethod(
	ProfileMethodInfo(MethodReference(dex, method_idx), inline_caches), flags, annotation);
	}

	static bool AddClass(ProfileCompilationInfo* info,
	const DexFile* dex,
	dex::TypeIndex type_index,
	const ProfileSampleAnnotation& annotation = ProfileSampleAnnotation::kNone) {
	return info->AddClass(*dex, type_index, annotation);
	}

	static bool ProfileIndexMatchesDexFile(const ProfileCompilationInfo& info,
	ProfileIndexType profile_index,
	const DexFile* dex_file) {
	DCHECK(dex_file != nullptr);
	std::array<const DexFile*, 1u> dex_files{dex_file};
	return dex_file == info.FindDexFileForProfileIndex(profile_index, dex_files);
	}

	// Compare different representations of inline caches for equality.
	static bool EqualInlineCaches(const std::vector<ProfileMethodInfo::ProfileInlineCache>& expected,
	const DexFile* dex_file,
	const ProfileCompilationInfo::MethodHotness& actual_hotness,
	const ProfileCompilationInfo& info) {
	CHECK(actual_hotness.IsHot());
	CHECK(actual_hotness.GetInlineCacheMap() != nullptr);
	const ProfileCompilationInfo::InlineCacheMap& actual = *actual_hotness.GetInlineCacheMap();
	if (expected.size() != actual.size()) {
	return false;
	}
	// The `expected` data should be sorted by dex pc.
	CHECK(std::is_sorted(expected.begin(),
	expected.end(),
	[](auto&& lhs, auto&& rhs) { return lhs.dex_pc < rhs.dex_pc; }));
	// The `actual` data is a map sorted by dex pc, so we can just iterate over both.
	auto expected_it = expected.begin();
	for (auto it = actual.begin(), end = actual.end(); it != end; ++it, ++expected_it) {
	uint32_t dex_pc = it->first;
	const ProfileCompilationInfo::DexPcData& dex_pc_data = it->second;
	if (dex_pc != expected_it->dex_pc) {
	return false;
	}
	if (dex_pc_data.is_missing_types != expected_it->is_missing_types) {
	return false;
	} else if (dex_pc_data.is_missing_types) {
	continue; // The classes do not matter if we're missing some types.
	}
	// The `expected_it->is_megamorphic` is not initialized. Check the number of classes.
	bool expected_is_megamorphic =
	(expected_it->classes.size() >= ProfileCompilationInfo::kIndividualInlineCacheSize);
	if (dex_pc_data.is_megamorphic != expected_is_megamorphic) {
	return false;
	} else if (dex_pc_data.is_megamorphic) {
	continue; // The classes do not matter if the inline cache is megamorphic.
	}
	if (dex_pc_data.classes.size() != expected_it->classes.size()) {
	return false;
	}
	for (dex::TypeIndex type_index : dex_pc_data.classes) {
	if (std::none_of(expected_it->classes.begin(),
	expected_it->classes.end(),
	[&](const TypeReference& type_ref) {
	if (type_ref.dex_file == dex_file) {
	return type_index == type_ref.TypeIndex();
	} else {
	const char* expected_descriptor =
	type_ref.dex_file->StringByTypeIdx(type_ref.TypeIndex());
	const char* descriptor = info.GetTypeDescriptor(dex_file, type_index);
	return strcmp(expected_descriptor, descriptor) == 0;
	}
	})) {
	return false;
	}
	}
	}
	return true;
	}

	protected:
	static constexpr size_t kNumSharedTypes = 10u;

	const DexFile* BuildDex(const std::string& location,
	uint32_t location_checksum,
	const std::string& class_descriptor,
	size_t num_method_ids,
	size_t num_class_ids = kNumSharedTypes + 1u) {
	TestDexFileBuilder builder;
	builder.AddType(class_descriptor);
	CHECK_NE(num_class_ids, 0u);
	size_t num_shared_ids = std::min(num_class_ids - 1u, kNumSharedTypes);
	for (size_t shared_type_index = 0; shared_type_index != num_shared_ids; ++shared_type_index) {
	builder.AddType("LSharedType" + std::to_string(shared_type_index) + ";");
	}
	for (size_t i = 1u + num_shared_ids; i < num_class_ids; ++i) {
	builder.AddType("LFiller" + std::to_string(i) + ";");
	}
	for (size_t method_index = 0; method_index != num_method_ids; ++method_index) {
	// Some tests add the maximum number of methods (`num_method_ids` is 2^16) and we
	// do not want to waste memory with that many unique name strings (with identical
	// proto id). So create up to num_shared_ids^2 proto ids and only
	// num_method_ids/num_shared_ids^2 names.
	size_t return_type_index = method_index % num_shared_ids;
	size_t arg_type_index = (method_index / num_shared_ids) % num_shared_ids;
	size_t method_name_index = (method_index / num_shared_ids) / num_shared_ids;
	std::string return_type = "LSharedType" + std::to_string(return_type_index) + ";";
	std::string arg_type = "LSharedType" + std::to_string(arg_type_index) + ";";
	std::string signature = ART_FORMAT("({}){}", arg_type, return_type);
	builder.AddMethod(class_descriptor, signature, "m" + std::to_string(method_name_index));
	}
	storage.push_back(builder.Build(location, location_checksum));
	return storage.back().get();
	}

	std::vector<std::unique_ptr<const DexFile>> storage;
	};

	} // namespace art

	#endif // ART_LIBPROFILE_PROFILE_PROFILE_TEST_HELPER_H_