compiler/driver/compiler_options.h - platform/art - Gitiles

 /*
  * Copyright (C) 2014 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_COMPILER_DRIVER_COMPILER_OPTIONS_H_
 #define ART_COMPILER_DRIVER_COMPILER_OPTIONS_H_

 #include <ostream>
 #include <string>
 #include <vector>

 #include "base/globals.h"
 #include "base/macros.h"
 #include "base/utils.h"
 #include "compiler_filter.h"
 #include "optimizing/register_allocator.h"

 namespace art {

 namespace verifier {
 class VerifierDepsTest;
 }  // namespace verifier

 class DexFile;

 class CompilerOptions FINAL {
  public:
   // Guide heuristics to determine whether to compile method if profile data not available.
   static const size_t kDefaultHugeMethodThreshold = 10000;
   static const size_t kDefaultLargeMethodThreshold = 600;
   static const size_t kDefaultSmallMethodThreshold = 60;
   static const size_t kDefaultTinyMethodThreshold = 20;
   static const size_t kDefaultNumDexMethodsThreshold = 900;
   static constexpr double kDefaultTopKProfileThreshold = 90.0;
   static const bool kDefaultGenerateDebugInfo = false;
   static const bool kDefaultGenerateMiniDebugInfo = false;
   static const size_t kDefaultInlineMaxCodeUnits = 32;
   static constexpr size_t kUnsetInlineMaxCodeUnits = -1;

   CompilerOptions();
   ~CompilerOptions();

   CompilerFilter::Filter GetCompilerFilter() const {
     return compiler_filter_;
   }

   void SetCompilerFilter(CompilerFilter::Filter compiler_filter) {
     compiler_filter_ = compiler_filter;
   }

   bool IsAotCompilationEnabled() const {
     return CompilerFilter::IsAotCompilationEnabled(compiler_filter_);
   }

   bool IsJniCompilationEnabled() const {
     return CompilerFilter::IsJniCompilationEnabled(compiler_filter_);
   }

   bool IsQuickeningCompilationEnabled() const {
     return CompilerFilter::IsQuickeningCompilationEnabled(compiler_filter_);
   }

   bool IsVerificationEnabled() const {
     return CompilerFilter::IsVerificationEnabled(compiler_filter_);
   }

   bool AssumeClassesAreVerified() const {
     return compiler_filter_ == CompilerFilter::kAssumeVerified;
   }

   bool VerifyAtRuntime() const {
     return compiler_filter_ == CompilerFilter::kExtract;
   }

   bool IsAnyCompilationEnabled() const {
     return CompilerFilter::IsAnyCompilationEnabled(compiler_filter_);
   }

   size_t GetHugeMethodThreshold() const {
     return huge_method_threshold_;
   }

   size_t GetLargeMethodThreshold() const {
     return large_method_threshold_;
   }

   size_t GetSmallMethodThreshold() const {
     return small_method_threshold_;
   }

   size_t GetTinyMethodThreshold() const {
     return tiny_method_threshold_;
   }

   bool IsHugeMethod(size_t num_dalvik_instructions) const {
     return num_dalvik_instructions > huge_method_threshold_;
   }

   bool IsLargeMethod(size_t num_dalvik_instructions) const {
     return num_dalvik_instructions > large_method_threshold_;
   }

   bool IsSmallMethod(size_t num_dalvik_instructions) const {
     return num_dalvik_instructions > small_method_threshold_;
   }

   bool IsTinyMethod(size_t num_dalvik_instructions) const {
     return num_dalvik_instructions > tiny_method_threshold_;
   }

   size_t GetNumDexMethodsThreshold() const {
     return num_dex_methods_threshold_;
   }

   size_t GetInlineMaxCodeUnits() const {
     return inline_max_code_units_;
   }
   void SetInlineMaxCodeUnits(size_t units) {
     inline_max_code_units_ = units;
   }

   double GetTopKProfileThreshold() const {
     return top_k_profile_threshold_;
   }

   bool GetDebuggable() const {
     return debuggable_;
   }

   void SetDebuggable(bool value) {
     debuggable_ = value;
   }

   bool GetNativeDebuggable() const {
     return GetDebuggable() && GetGenerateDebugInfo();
   }

   // This flag controls whether the compiler collects debugging information.
   // The other flags control how the information is written to disk.
   bool GenerateAnyDebugInfo() const {
     return GetGenerateDebugInfo() || GetGenerateMiniDebugInfo();
   }

   bool GetGenerateDebugInfo() const {
     return generate_debug_info_;
   }

   bool GetGenerateMiniDebugInfo() const {
     return generate_mini_debug_info_;
   }

   // Should run-time checks be emitted in debug mode?
   bool EmitRunTimeChecksInDebugMode() const;

   bool GetGenerateBuildId() const {
     return generate_build_id_;
   }

   bool GetImplicitNullChecks() const {
     return implicit_null_checks_;
   }

   bool GetImplicitStackOverflowChecks() const {
     return implicit_so_checks_;
   }

   bool GetImplicitSuspendChecks() const {
     return implicit_suspend_checks_;
   }

   // Are we compiling a boot image?
   bool IsBootImage() const {
     return boot_image_;
   }

   // Are we compiling a core image (small boot image only used for ART testing)?
   bool IsCoreImage() const {
     // Ensure that `core_image_` => `boot_image_`.
     DCHECK(!core_image_ || boot_image_);
     return core_image_;
   }

   // Are we compiling an app image?
   bool IsAppImage() const {
     return app_image_;
   }

   void DisableAppImage() {
     app_image_ = false;
   }

   // Should the code be compiled as position independent?
   bool GetCompilePic() const {
     return compile_pic_;
   }

   bool HasVerboseMethods() const {
     return !verbose_methods_.empty();
   }

   bool IsVerboseMethod(const std::string& pretty_method) const {
     for (const std::string& cur_method : verbose_methods_) {
       if (pretty_method.find(cur_method) != std::string::npos) {
         return true;
       }
     }
     return false;
   }

   std::ostream* GetInitFailureOutput() const {
     return init_failure_output_.get();
   }

   bool AbortOnHardVerifierFailure() const {
     return abort_on_hard_verifier_failure_;
   }
   bool AbortOnSoftVerifierFailure() const {
     return abort_on_soft_verifier_failure_;
   }

   const std::vector<const DexFile*>* GetNoInlineFromDexFile() const {
     return no_inline_from_;
   }

   bool ParseCompilerOptions(const std::vector<std::string>& options,
                             bool ignore_unrecognized,
                             std::string* error_msg);

   void SetNonPic() {
     compile_pic_ = false;
   }

   const std::string& GetDumpCfgFileName() const {
     return dump_cfg_file_name_;
   }

   bool GetDumpCfgAppend() const {
     return dump_cfg_append_;
   }

   bool IsForceDeterminism() const {
     return force_determinism_;
   }

   bool DeduplicateCode() const {
     return deduplicate_code_;
   }

   RegisterAllocator::Strategy GetRegisterAllocationStrategy() const {
     return register_allocation_strategy_;
   }

   const std::vector<std::string>* GetPassesToRun() const {
     return passes_to_run_;
   }

   bool GetDumpTimings() const {
     return dump_timings_;
   }

   bool GetDumpPassTimings() const {
     return dump_pass_timings_;
   }

   bool GetDumpStats() const {
     return dump_stats_;
   }

   bool CountHotnessInCompiledCode() const {
     return count_hotness_in_compiled_code_;
   }

  private:
   bool ParseDumpInitFailures(const std::string& option, std::string* error_msg);
   void ParseDumpCfgPasses(const StringPiece& option, UsageFn Usage);
   void ParseInlineMaxCodeUnits(const StringPiece& option, UsageFn Usage);
   void ParseNumDexMethods(const StringPiece& option, UsageFn Usage);
   void ParseTinyMethodMax(const StringPiece& option, UsageFn Usage);
   void ParseSmallMethodMax(const StringPiece& option, UsageFn Usage);
   void ParseLargeMethodMax(const StringPiece& option, UsageFn Usage);
   void ParseHugeMethodMax(const StringPiece& option, UsageFn Usage);
   bool ParseRegisterAllocationStrategy(const std::string& option, std::string* error_msg);

   CompilerFilter::Filter compiler_filter_;
   size_t huge_method_threshold_;
   size_t large_method_threshold_;
   size_t small_method_threshold_;
   size_t tiny_method_threshold_;
   size_t num_dex_methods_threshold_;
   size_t inline_max_code_units_;

   // Dex files from which we should not inline code.
   // This is usually a very short list (i.e. a single dex file), so we
   // prefer vector<> over a lookup-oriented container, such as set<>.
   const std::vector<const DexFile*>* no_inline_from_;

   bool boot_image_;
   bool core_image_;
   bool app_image_;
   // When using a profile file only the top K% of the profiled samples will be compiled.
   double top_k_profile_threshold_;
   bool debuggable_;
   bool generate_debug_info_;
   bool generate_mini_debug_info_;
   bool generate_build_id_;
   bool implicit_null_checks_;
   bool implicit_so_checks_;
   bool implicit_suspend_checks_;
   bool compile_pic_;
   bool dump_timings_;
   bool dump_pass_timings_;
   bool dump_stats_;

   // Vector of methods to have verbose output enabled for.
   std::vector<std::string> verbose_methods_;

   // Abort compilation with an error if we find a class that fails verification with a hard
   // failure.
   bool abort_on_hard_verifier_failure_;
   // Same for soft failures.
   bool abort_on_soft_verifier_failure_;

   // Log initialization of initialization failures to this stream if not null.
   std::unique_ptr<std::ostream> init_failure_output_;

   std::string dump_cfg_file_name_;
   bool dump_cfg_append_;

   // Whether the compiler should trade performance for determinism to guarantee exactly reproducible
   // outcomes.
   bool force_determinism_;

   // Whether code should be deduplicated.
   bool deduplicate_code_;

   // Whether compiled code should increment the hotness count of ArtMethod. Note that the increments
   // won't be atomic for performance reasons, so we accept races, just like in interpreter.
   bool count_hotness_in_compiled_code_;

   RegisterAllocator::Strategy register_allocation_strategy_;

   // If not null, specifies optimization passes which will be run instead of defaults.
   // Note that passes_to_run_ is not checked for correctness and providing an incorrect
   // list of passes can lead to unexpected compiler behaviour. This is caused by dependencies
   // between passes. Failing to satisfy them can for example lead to compiler crashes.
   // Passing pass names which are not recognized by the compiler will result in
   // compiler-dependant behavior.
   const std::vector<std::string>* passes_to_run_;

   friend class Dex2Oat;
   friend class DexToDexDecompilerTest;
   friend class CommonCompilerTest;
   friend class verifier::VerifierDepsTest;

   template <class Base>
   friend bool ReadCompilerOptions(Base& map, CompilerOptions* options, std::string* error_msg);

   DISALLOW_COPY_AND_ASSIGN(CompilerOptions);
 };

 }  // namespace art

 #endif  // ART_COMPILER_DRIVER_COMPILER_OPTIONS_H_
	/*
	* Copyright (C) 2014 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_COMPILER_DRIVER_COMPILER_OPTIONS_H_
	#define ART_COMPILER_DRIVER_COMPILER_OPTIONS_H_

	#include <ostream>
	#include <string>
	#include <vector>

	#include "base/globals.h"
	#include "base/macros.h"
	#include "base/utils.h"
	#include "compiler_filter.h"
	#include "optimizing/register_allocator.h"

	namespace art {

	namespace verifier {
	class VerifierDepsTest;
	} // namespace verifier

	class DexFile;

	class CompilerOptions FINAL {
	public:
	// Guide heuristics to determine whether to compile method if profile data not available.
	static const size_t kDefaultHugeMethodThreshold = 10000;
	static const size_t kDefaultLargeMethodThreshold = 600;
	static const size_t kDefaultSmallMethodThreshold = 60;
	static const size_t kDefaultTinyMethodThreshold = 20;
	static const size_t kDefaultNumDexMethodsThreshold = 900;
	static constexpr double kDefaultTopKProfileThreshold = 90.0;
	static const bool kDefaultGenerateDebugInfo = false;
	static const bool kDefaultGenerateMiniDebugInfo = false;
	static const size_t kDefaultInlineMaxCodeUnits = 32;
	static constexpr size_t kUnsetInlineMaxCodeUnits = -1;

	CompilerOptions();
	~CompilerOptions();

	CompilerFilter::Filter GetCompilerFilter() const {
	return compiler_filter_;
	}

	void SetCompilerFilter(CompilerFilter::Filter compiler_filter) {
	compiler_filter_ = compiler_filter;
	}

	bool IsAotCompilationEnabled() const {
	return CompilerFilter::IsAotCompilationEnabled(compiler_filter_);
	}

	bool IsJniCompilationEnabled() const {
	return CompilerFilter::IsJniCompilationEnabled(compiler_filter_);
	}

	bool IsQuickeningCompilationEnabled() const {
	return CompilerFilter::IsQuickeningCompilationEnabled(compiler_filter_);
	}

	bool IsVerificationEnabled() const {
	return CompilerFilter::IsVerificationEnabled(compiler_filter_);
	}

	bool AssumeClassesAreVerified() const {
	return compiler_filter_ == CompilerFilter::kAssumeVerified;
	}

	bool VerifyAtRuntime() const {
	return compiler_filter_ == CompilerFilter::kExtract;
	}

	bool IsAnyCompilationEnabled() const {
	return CompilerFilter::IsAnyCompilationEnabled(compiler_filter_);
	}

	size_t GetHugeMethodThreshold() const {
	return huge_method_threshold_;
	}

	size_t GetLargeMethodThreshold() const {
	return large_method_threshold_;
	}

	size_t GetSmallMethodThreshold() const {
	return small_method_threshold_;
	}

	size_t GetTinyMethodThreshold() const {
	return tiny_method_threshold_;
	}

	bool IsHugeMethod(size_t num_dalvik_instructions) const {
	return num_dalvik_instructions > huge_method_threshold_;
	}

	bool IsLargeMethod(size_t num_dalvik_instructions) const {
	return num_dalvik_instructions > large_method_threshold_;
	}

	bool IsSmallMethod(size_t num_dalvik_instructions) const {
	return num_dalvik_instructions > small_method_threshold_;
	}

	bool IsTinyMethod(size_t num_dalvik_instructions) const {
	return num_dalvik_instructions > tiny_method_threshold_;
	}

	size_t GetNumDexMethodsThreshold() const {
	return num_dex_methods_threshold_;
	}

	size_t GetInlineMaxCodeUnits() const {
	return inline_max_code_units_;
	}
	void SetInlineMaxCodeUnits(size_t units) {
	inline_max_code_units_ = units;
	}

	double GetTopKProfileThreshold() const {
	return top_k_profile_threshold_;
	}

	bool GetDebuggable() const {
	return debuggable_;
	}

	void SetDebuggable(bool value) {
	debuggable_ = value;
	}

	bool GetNativeDebuggable() const {
	return GetDebuggable() && GetGenerateDebugInfo();
	}

	// This flag controls whether the compiler collects debugging information.
	// The other flags control how the information is written to disk.
	bool GenerateAnyDebugInfo() const {
	return GetGenerateDebugInfo() \|\| GetGenerateMiniDebugInfo();
	}

	bool GetGenerateDebugInfo() const {
	return generate_debug_info_;
	}

	bool GetGenerateMiniDebugInfo() const {
	return generate_mini_debug_info_;
	}

	// Should run-time checks be emitted in debug mode?
	bool EmitRunTimeChecksInDebugMode() const;

	bool GetGenerateBuildId() const {
	return generate_build_id_;
	}

	bool GetImplicitNullChecks() const {
	return implicit_null_checks_;
	}

	bool GetImplicitStackOverflowChecks() const {
	return implicit_so_checks_;
	}

	bool GetImplicitSuspendChecks() const {
	return implicit_suspend_checks_;
	}

	// Are we compiling a boot image?
	bool IsBootImage() const {
	return boot_image_;
	}

	// Are we compiling a core image (small boot image only used for ART testing)?
	bool IsCoreImage() const {
	// Ensure that `core_image_` => `boot_image_`.
	DCHECK(!core_image_ \|\| boot_image_);
	return core_image_;
	}

	// Are we compiling an app image?
	bool IsAppImage() const {
	return app_image_;
	}

	void DisableAppImage() {
	app_image_ = false;
	}

	// Should the code be compiled as position independent?
	bool GetCompilePic() const {
	return compile_pic_;
	}

	bool HasVerboseMethods() const {
	return !verbose_methods_.empty();
	}

	bool IsVerboseMethod(const std::string& pretty_method) const {
	for (const std::string& cur_method : verbose_methods_) {
	if (pretty_method.find(cur_method) != std::string::npos) {
	return true;
	}
	}
	return false;
	}

	std::ostream* GetInitFailureOutput() const {
	return init_failure_output_.get();
	}

	bool AbortOnHardVerifierFailure() const {
	return abort_on_hard_verifier_failure_;
	}
	bool AbortOnSoftVerifierFailure() const {
	return abort_on_soft_verifier_failure_;
	}

	const std::vector<const DexFile> GetNoInlineFromDexFile() const {
	return no_inline_from_;
	}

	bool ParseCompilerOptions(const std::vector<std::string>& options,
	bool ignore_unrecognized,
	std::string* error_msg);

	void SetNonPic() {
	compile_pic_ = false;
	}

	const std::string& GetDumpCfgFileName() const {
	return dump_cfg_file_name_;
	}

	bool GetDumpCfgAppend() const {
	return dump_cfg_append_;
	}

	bool IsForceDeterminism() const {
	return force_determinism_;
	}

	bool DeduplicateCode() const {
	return deduplicate_code_;
	}

	RegisterAllocator::Strategy GetRegisterAllocationStrategy() const {
	return register_allocation_strategy_;
	}

	const std::vector<std::string>* GetPassesToRun() const {
	return passes_to_run_;
	}

	bool GetDumpTimings() const {
	return dump_timings_;
	}

	bool GetDumpPassTimings() const {
	return dump_pass_timings_;
	}

	bool GetDumpStats() const {
	return dump_stats_;
	}

	bool CountHotnessInCompiledCode() const {
	return count_hotness_in_compiled_code_;
	}

	private:
	bool ParseDumpInitFailures(const std::string& option, std::string* error_msg);
	void ParseDumpCfgPasses(const StringPiece& option, UsageFn Usage);
	void ParseInlineMaxCodeUnits(const StringPiece& option, UsageFn Usage);
	void ParseNumDexMethods(const StringPiece& option, UsageFn Usage);
	void ParseTinyMethodMax(const StringPiece& option, UsageFn Usage);
	void ParseSmallMethodMax(const StringPiece& option, UsageFn Usage);
	void ParseLargeMethodMax(const StringPiece& option, UsageFn Usage);
	void ParseHugeMethodMax(const StringPiece& option, UsageFn Usage);
	bool ParseRegisterAllocationStrategy(const std::string& option, std::string* error_msg);

	CompilerFilter::Filter compiler_filter_;
	size_t huge_method_threshold_;
	size_t large_method_threshold_;
	size_t small_method_threshold_;
	size_t tiny_method_threshold_;
	size_t num_dex_methods_threshold_;
	size_t inline_max_code_units_;

	// Dex files from which we should not inline code.
	// This is usually a very short list (i.e. a single dex file), so we
	// prefer vector<> over a lookup-oriented container, such as set<>.
	const std::vector<const DexFile> no_inline_from_;

	bool boot_image_;
	bool core_image_;
	bool app_image_;
	// When using a profile file only the top K% of the profiled samples will be compiled.
	double top_k_profile_threshold_;
	bool debuggable_;
	bool generate_debug_info_;
	bool generate_mini_debug_info_;
	bool generate_build_id_;
	bool implicit_null_checks_;
	bool implicit_so_checks_;
	bool implicit_suspend_checks_;
	bool compile_pic_;
	bool dump_timings_;
	bool dump_pass_timings_;
	bool dump_stats_;

	// Vector of methods to have verbose output enabled for.
	std::vector<std::string> verbose_methods_;

	// Abort compilation with an error if we find a class that fails verification with a hard
	// failure.
	bool abort_on_hard_verifier_failure_;
	// Same for soft failures.
	bool abort_on_soft_verifier_failure_;

	// Log initialization of initialization failures to this stream if not null.
	std::unique_ptr<std::ostream> init_failure_output_;

	std::string dump_cfg_file_name_;
	bool dump_cfg_append_;

	// Whether the compiler should trade performance for determinism to guarantee exactly reproducible
	// outcomes.
	bool force_determinism_;

	// Whether code should be deduplicated.
	bool deduplicate_code_;

	// Whether compiled code should increment the hotness count of ArtMethod. Note that the increments
	// won't be atomic for performance reasons, so we accept races, just like in interpreter.
	bool count_hotness_in_compiled_code_;

	RegisterAllocator::Strategy register_allocation_strategy_;

	// If not null, specifies optimization passes which will be run instead of defaults.
	// Note that passes_to_run_ is not checked for correctness and providing an incorrect
	// list of passes can lead to unexpected compiler behaviour. This is caused by dependencies
	// between passes. Failing to satisfy them can for example lead to compiler crashes.
	// Passing pass names which are not recognized by the compiler will result in
	// compiler-dependant behavior.
	const std::vector<std::string>* passes_to_run_;

	friend class Dex2Oat;
	friend class DexToDexDecompilerTest;
	friend class CommonCompilerTest;
	friend class verifier::VerifierDepsTest;

	template <class Base>
	friend bool ReadCompilerOptions(Base& map, CompilerOptions* options, std::string* error_msg);

	DISALLOW_COPY_AND_ASSIGN(CompilerOptions);
	};

	} // namespace art

	#endif // ART_COMPILER_DRIVER_COMPILER_OPTIONS_H_