/* * Copyright (C) 2011 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_RUNTIME_DEX_FILE_H_ #define ART_RUNTIME_DEX_FILE_H_ #include <memory> #include <string> #include <unordered_map> #include <vector> #include "base/logging.h" #include "base/mutex.h" // For Locks::mutator_lock_. #include "base/value_object.h" #include "globals.h" #include "invoke_type.h" #include "jni.h" #include "jvalue.h" #include "mirror/object_array.h" #include "modifiers.h" #include "utf.h" namespace art { // TODO: remove dependencies on mirror classes, primarily by moving // EncodedStaticFieldValueIterator to its own file. namespace mirror { class ClassLoader; class DexCache; } // namespace mirror class ArtField; class ArtMethod; class ClassLinker; template <class Key, class Value, class EmptyFn, class HashFn, class Pred, class Alloc> class HashMap; class MemMap; class OatDexFile; class Signature; template<class T> class Handle; class StringPiece; class TypeLookupTable; class ZipArchive; // TODO: move all of the macro functionality into the DexCache class. class DexFile { public: // First Dex format version supporting default methods. static const uint32_t kDefaultMethodsVersion = 37; // First Dex format version enforcing class definition ordering rules. static const uint32_t kClassDefinitionOrderEnforcedVersion = 37; static const uint8_t kDexMagic[]; static constexpr size_t kNumDexVersions = 2; static constexpr size_t kDexVersionLen = 4; static const uint8_t kDexMagicVersions[kNumDexVersions][kDexVersionLen]; static constexpr size_t kSha1DigestSize = 20; static constexpr uint32_t kDexEndianConstant = 0x12345678; // name of the DexFile entry within a zip archive static const char* kClassesDex; // The value of an invalid index. static const uint32_t kDexNoIndex = 0xFFFFFFFF; // The value of an invalid index. static const uint16_t kDexNoIndex16 = 0xFFFF; // The separator character in MultiDex locations. static constexpr char kMultiDexSeparator = ':'; // A string version of the previous. This is a define so that we can merge string literals in the // preprocessor. #define kMultiDexSeparatorString ":" // Raw header_item. struct Header { uint8_t magic_[8]; uint32_t checksum_; // See also location_checksum_ uint8_t signature_[kSha1DigestSize]; uint32_t file_size_; // size of entire file uint32_t header_size_; // offset to start of next section uint32_t endian_tag_; uint32_t link_size_; // unused uint32_t link_off_; // unused uint32_t map_off_; // unused uint32_t string_ids_size_; // number of StringIds uint32_t string_ids_off_; // file offset of StringIds array uint32_t type_ids_size_; // number of TypeIds, we don't support more than 65535 uint32_t type_ids_off_; // file offset of TypeIds array uint32_t proto_ids_size_; // number of ProtoIds, we don't support more than 65535 uint32_t proto_ids_off_; // file offset of ProtoIds array uint32_t field_ids_size_; // number of FieldIds uint32_t field_ids_off_; // file offset of FieldIds array uint32_t method_ids_size_; // number of MethodIds uint32_t method_ids_off_; // file offset of MethodIds array uint32_t class_defs_size_; // number of ClassDefs uint32_t class_defs_off_; // file offset of ClassDef array uint32_t data_size_; // unused uint32_t data_off_; // unused // Decode the dex magic version uint32_t GetVersion() const; private: DISALLOW_COPY_AND_ASSIGN(Header); }; // Map item type codes. enum { kDexTypeHeaderItem = 0x0000, kDexTypeStringIdItem = 0x0001, kDexTypeTypeIdItem = 0x0002, kDexTypeProtoIdItem = 0x0003, kDexTypeFieldIdItem = 0x0004, kDexTypeMethodIdItem = 0x0005, kDexTypeClassDefItem = 0x0006, kDexTypeMapList = 0x1000, kDexTypeTypeList = 0x1001, kDexTypeAnnotationSetRefList = 0x1002, kDexTypeAnnotationSetItem = 0x1003, kDexTypeClassDataItem = 0x2000, kDexTypeCodeItem = 0x2001, kDexTypeStringDataItem = 0x2002, kDexTypeDebugInfoItem = 0x2003, kDexTypeAnnotationItem = 0x2004, kDexTypeEncodedArrayItem = 0x2005, kDexTypeAnnotationsDirectoryItem = 0x2006, }; struct MapItem { uint16_t type_; uint16_t unused_; uint32_t size_; uint32_t offset_; private: DISALLOW_COPY_AND_ASSIGN(MapItem); }; struct MapList { uint32_t size_; MapItem list_[1]; private: DISALLOW_COPY_AND_ASSIGN(MapList); }; // Raw string_id_item. struct StringId { uint32_t string_data_off_; // offset in bytes from the base address private: DISALLOW_COPY_AND_ASSIGN(StringId); }; // Raw type_id_item. struct TypeId { uint32_t descriptor_idx_; // index into string_ids private: DISALLOW_COPY_AND_ASSIGN(TypeId); }; // Raw field_id_item. struct FieldId { uint16_t class_idx_; // index into type_ids_ array for defining class uint16_t type_idx_; // index into type_ids_ array for field type uint32_t name_idx_; // index into string_ids_ array for field name private: DISALLOW_COPY_AND_ASSIGN(FieldId); }; // Raw method_id_item. struct MethodId { uint16_t class_idx_; // index into type_ids_ array for defining class uint16_t proto_idx_; // index into proto_ids_ array for method prototype uint32_t name_idx_; // index into string_ids_ array for method name private: DISALLOW_COPY_AND_ASSIGN(MethodId); }; // Raw proto_id_item. struct ProtoId { uint32_t shorty_idx_; // index into string_ids array for shorty descriptor uint16_t return_type_idx_; // index into type_ids array for return type uint16_t pad_; // padding = 0 uint32_t parameters_off_; // file offset to type_list for parameter types private: DISALLOW_COPY_AND_ASSIGN(ProtoId); }; // Raw class_def_item. struct ClassDef { uint16_t class_idx_; // index into type_ids_ array for this class uint16_t pad1_; // padding = 0 uint32_t access_flags_; uint16_t superclass_idx_; // index into type_ids_ array for superclass uint16_t pad2_; // padding = 0 uint32_t interfaces_off_; // file offset to TypeList uint32_t source_file_idx_; // index into string_ids_ for source file name uint32_t annotations_off_; // file offset to annotations_directory_item uint32_t class_data_off_; // file offset to class_data_item uint32_t static_values_off_; // file offset to EncodedArray // Returns the valid access flags, that is, Java modifier bits relevant to the ClassDef type // (class or interface). These are all in the lower 16b and do not contain runtime flags. uint32_t GetJavaAccessFlags() const { // Make sure that none of our runtime-only flags are set. static_assert((kAccValidClassFlags & kAccJavaFlagsMask) == kAccValidClassFlags, "Valid class flags not a subset of Java flags"); static_assert((kAccValidInterfaceFlags & kAccJavaFlagsMask) == kAccValidInterfaceFlags, "Valid interface flags not a subset of Java flags"); if ((access_flags_ & kAccInterface) != 0) { // Interface. return access_flags_ & kAccValidInterfaceFlags; } else { // Class. return access_flags_ & kAccValidClassFlags; } } private: DISALLOW_COPY_AND_ASSIGN(ClassDef); }; // Raw type_item. struct TypeItem { uint16_t type_idx_; // index into type_ids section private: DISALLOW_COPY_AND_ASSIGN(TypeItem); }; // Raw type_list. class TypeList { public: uint32_t Size() const { return size_; } const TypeItem& GetTypeItem(uint32_t idx) const { DCHECK_LT(idx, this->size_); return this->list_[idx]; } // Size in bytes of the part of the list that is common. static constexpr size_t GetHeaderSize() { return 4U; } // Size in bytes of the whole type list including all the stored elements. static constexpr size_t GetListSize(size_t count) { return GetHeaderSize() + sizeof(TypeItem) * count; } private: uint32_t size_; // size of the list, in entries TypeItem list_[1]; // elements of the list DISALLOW_COPY_AND_ASSIGN(TypeList); }; // Raw code_item. struct CodeItem { uint16_t registers_size_; // the number of registers used by this code // (locals + parameters) uint16_t ins_size_; // the number of words of incoming arguments to the method // that this code is for uint16_t outs_size_; // the number of words of outgoing argument space required // by this code for method invocation uint16_t tries_size_; // the number of try_items for this instance. If non-zero, // then these appear as the tries array just after the // insns in this instance. uint32_t debug_info_off_; // file offset to debug info stream uint32_t insns_size_in_code_units_; // size of the insns array, in 2 byte code units uint16_t insns_[1]; // actual array of bytecode. private: DISALLOW_COPY_AND_ASSIGN(CodeItem); }; // Raw try_item. struct TryItem { uint32_t start_addr_; uint16_t insn_count_; uint16_t handler_off_; private: DISALLOW_COPY_AND_ASSIGN(TryItem); }; // Annotation constants. enum { kDexVisibilityBuild = 0x00, /* annotation visibility */ kDexVisibilityRuntime = 0x01, kDexVisibilitySystem = 0x02, kDexAnnotationByte = 0x00, kDexAnnotationShort = 0x02, kDexAnnotationChar = 0x03, kDexAnnotationInt = 0x04, kDexAnnotationLong = 0x06, kDexAnnotationFloat = 0x10, kDexAnnotationDouble = 0x11, kDexAnnotationString = 0x17, kDexAnnotationType = 0x18, kDexAnnotationField = 0x19, kDexAnnotationMethod = 0x1a, kDexAnnotationEnum = 0x1b, kDexAnnotationArray = 0x1c, kDexAnnotationAnnotation = 0x1d, kDexAnnotationNull = 0x1e, kDexAnnotationBoolean = 0x1f, kDexAnnotationValueTypeMask = 0x1f, /* low 5 bits */ kDexAnnotationValueArgShift = 5, }; struct AnnotationsDirectoryItem { uint32_t class_annotations_off_; uint32_t fields_size_; uint32_t methods_size_; uint32_t parameters_size_; private: DISALLOW_COPY_AND_ASSIGN(AnnotationsDirectoryItem); }; struct FieldAnnotationsItem { uint32_t field_idx_; uint32_t annotations_off_; private: DISALLOW_COPY_AND_ASSIGN(FieldAnnotationsItem); }; struct MethodAnnotationsItem { uint32_t method_idx_; uint32_t annotations_off_; private: DISALLOW_COPY_AND_ASSIGN(MethodAnnotationsItem); }; struct ParameterAnnotationsItem { uint32_t method_idx_; uint32_t annotations_off_; private: DISALLOW_COPY_AND_ASSIGN(ParameterAnnotationsItem); }; struct AnnotationSetRefItem { uint32_t annotations_off_; private: DISALLOW_COPY_AND_ASSIGN(AnnotationSetRefItem); }; struct AnnotationSetRefList { uint32_t size_; AnnotationSetRefItem list_[1]; private: DISALLOW_COPY_AND_ASSIGN(AnnotationSetRefList); }; struct AnnotationSetItem { uint32_t size_; uint32_t entries_[1]; private: DISALLOW_COPY_AND_ASSIGN(AnnotationSetItem); }; struct AnnotationItem { uint8_t visibility_; uint8_t annotation_[1]; private: DISALLOW_COPY_AND_ASSIGN(AnnotationItem); }; struct AnnotationValue { JValue value_; uint8_t type_; }; enum AnnotationResultStyle { // private kAllObjects, kPrimitivesOrObjects, kAllRaw }; // Returns the checksum of a file for comparison with GetLocationChecksum(). // For .dex files, this is the header checksum. // For zip files, this is the classes.dex zip entry CRC32 checksum. // Return true if the checksum could be found, false otherwise. static bool GetChecksum(const char* filename, uint32_t* checksum, std::string* error_msg); // Opens .dex files found in the container, guessing the container format based on file extension. static bool Open(const char* filename, const char* location, std::string* error_msg, std::vector<std::unique_ptr<const DexFile>>* dex_files); // Checks whether the given file has the dex magic, or is a zip file with a classes.dex entry. // If this function returns false, Open will not succeed. The inverse is not true, however. static bool MaybeDex(const char* filename); // Opens .dex file, backed by existing memory static std::unique_ptr<const DexFile> Open(const uint8_t* base, size_t size, const std::string& location, uint32_t location_checksum, const OatDexFile* oat_dex_file, bool verify, std::string* error_msg); // Open all classesXXX.dex files from a zip archive. static bool OpenFromZip(const ZipArchive& zip_archive, const std::string& location, std::string* error_msg, std::vector<std::unique_ptr<const DexFile>>* dex_files); // Closes a .dex file. virtual ~DexFile(); const std::string& GetLocation() const { return location_; } // For normal dex files, location and base location coincide. If a dex file is part of a multidex // archive, the base location is the name of the originating jar/apk, stripped of any internal // classes*.dex path. static std::string GetBaseLocation(const char* location) { const char* pos = strrchr(location, kMultiDexSeparator); if (pos == nullptr) { return location; } else { return std::string(location, pos - location); } } static std::string GetBaseLocation(const std::string& location) { return GetBaseLocation(location.c_str()); } // Returns the ':classes*.dex' part of the dex location. Returns an empty // string if there is no multidex suffix for the given location. // The kMultiDexSeparator is included in the returned suffix. static std::string GetMultiDexSuffix(const std::string& location) { size_t pos = location.rfind(kMultiDexSeparator); if (pos == std::string::npos) { return ""; } else { return location.substr(pos); } } std::string GetBaseLocation() const { return GetBaseLocation(location_); } // For DexFiles directly from .dex files, this is the checksum from the DexFile::Header. // For DexFiles opened from a zip files, this will be the ZipEntry CRC32 of classes.dex. uint32_t GetLocationChecksum() const { return location_checksum_; } const Header& GetHeader() const { DCHECK(header_ != nullptr) << GetLocation(); return *header_; } // Decode the dex magic version uint32_t GetVersion() const { return GetHeader().GetVersion(); } // Returns true if the byte string points to the magic value. static bool IsMagicValid(const uint8_t* magic); // Returns true if the byte string after the magic is the correct value. static bool IsVersionValid(const uint8_t* magic); // Returns the number of string identifiers in the .dex file. size_t NumStringIds() const { DCHECK(header_ != nullptr) << GetLocation(); return header_->string_ids_size_; } // Returns the StringId at the specified index. const StringId& GetStringId(uint32_t idx) const { DCHECK_LT(idx, NumStringIds()) << GetLocation(); return string_ids_[idx]; } uint32_t GetIndexForStringId(const StringId& string_id) const { CHECK_GE(&string_id, string_ids_) << GetLocation(); CHECK_LT(&string_id, string_ids_ + header_->string_ids_size_) << GetLocation(); return &string_id - string_ids_; } int32_t GetStringLength(const StringId& string_id) const; // Returns a pointer to the UTF-8 string data referred to by the given string_id as well as the // length of the string when decoded as a UTF-16 string. Note the UTF-16 length is not the same // as the string length of the string data. const char* GetStringDataAndUtf16Length(const StringId& string_id, uint32_t* utf16_length) const; const char* GetStringData(const StringId& string_id) const { uint32_t ignored; return GetStringDataAndUtf16Length(string_id, &ignored); } // Index version of GetStringDataAndUtf16Length. const char* StringDataAndUtf16LengthByIdx(uint32_t idx, uint32_t* utf16_length) const { if (idx == kDexNoIndex) { *utf16_length = 0; return nullptr; } const StringId& string_id = GetStringId(idx); return GetStringDataAndUtf16Length(string_id, utf16_length); } const char* StringDataByIdx(uint32_t idx) const { uint32_t unicode_length; return StringDataAndUtf16LengthByIdx(idx, &unicode_length); } // Looks up a string id for a given modified utf8 string. const StringId* FindStringId(const char* string) const; const TypeId* FindTypeId(const char* string) const; // Looks up a string id for a given utf16 string. const StringId* FindStringId(const uint16_t* string, size_t length) const; // Returns the number of type identifiers in the .dex file. uint32_t NumTypeIds() const { DCHECK(header_ != nullptr) << GetLocation(); return header_->type_ids_size_; } // Returns the TypeId at the specified index. const TypeId& GetTypeId(uint32_t idx) const { DCHECK_LT(idx, NumTypeIds()) << GetLocation(); return type_ids_[idx]; } uint16_t GetIndexForTypeId(const TypeId& type_id) const { CHECK_GE(&type_id, type_ids_) << GetLocation(); CHECK_LT(&type_id, type_ids_ + header_->type_ids_size_) << GetLocation(); size_t result = &type_id - type_ids_; DCHECK_LT(result, 65536U) << GetLocation(); return static_cast<uint16_t>(result); } // Get the descriptor string associated with a given type index. const char* StringByTypeIdx(uint32_t idx, uint32_t* unicode_length) const { const TypeId& type_id = GetTypeId(idx); return StringDataAndUtf16LengthByIdx(type_id.descriptor_idx_, unicode_length); } const char* StringByTypeIdx(uint32_t idx) const { const TypeId& type_id = GetTypeId(idx); return StringDataByIdx(type_id.descriptor_idx_); } // Returns the type descriptor string of a type id. const char* GetTypeDescriptor(const TypeId& type_id) const { return StringDataByIdx(type_id.descriptor_idx_); } // Looks up a type for the given string index const TypeId* FindTypeId(uint32_t string_idx) const; // Returns the number of field identifiers in the .dex file. size_t NumFieldIds() const { DCHECK(header_ != nullptr) << GetLocation(); return header_->field_ids_size_; } // Returns the FieldId at the specified index. const FieldId& GetFieldId(uint32_t idx) const { DCHECK_LT(idx, NumFieldIds()) << GetLocation(); return field_ids_[idx]; } uint32_t GetIndexForFieldId(const FieldId& field_id) const { CHECK_GE(&field_id, field_ids_) << GetLocation(); CHECK_LT(&field_id, field_ids_ + header_->field_ids_size_) << GetLocation(); return &field_id - field_ids_; } // Looks up a field by its declaring class, name and type const FieldId* FindFieldId(const DexFile::TypeId& declaring_klass, const DexFile::StringId& name, const DexFile::TypeId& type) const; // Returns the declaring class descriptor string of a field id. const char* GetFieldDeclaringClassDescriptor(const FieldId& field_id) const { const DexFile::TypeId& type_id = GetTypeId(field_id.class_idx_); return GetTypeDescriptor(type_id); } // Returns the class descriptor string of a field id. const char* GetFieldTypeDescriptor(const FieldId& field_id) const { const DexFile::TypeId& type_id = GetTypeId(field_id.type_idx_); return GetTypeDescriptor(type_id); } // Returns the name of a field id. const char* GetFieldName(const FieldId& field_id) const { return StringDataByIdx(field_id.name_idx_); } // Returns the number of method identifiers in the .dex file. size_t NumMethodIds() const { DCHECK(header_ != nullptr) << GetLocation(); return header_->method_ids_size_; } // Returns the MethodId at the specified index. const MethodId& GetMethodId(uint32_t idx) const { DCHECK_LT(idx, NumMethodIds()) << GetLocation(); return method_ids_[idx]; } uint32_t GetIndexForMethodId(const MethodId& method_id) const { CHECK_GE(&method_id, method_ids_) << GetLocation(); CHECK_LT(&method_id, method_ids_ + header_->method_ids_size_) << GetLocation(); return &method_id - method_ids_; } // Looks up a method by its declaring class, name and proto_id const MethodId* FindMethodId(const DexFile::TypeId& declaring_klass, const DexFile::StringId& name, const DexFile::ProtoId& signature) const; // Returns the declaring class descriptor string of a method id. const char* GetMethodDeclaringClassDescriptor(const MethodId& method_id) const { const DexFile::TypeId& type_id = GetTypeId(method_id.class_idx_); return GetTypeDescriptor(type_id); } // Returns the prototype of a method id. const ProtoId& GetMethodPrototype(const MethodId& method_id) const { return GetProtoId(method_id.proto_idx_); } // Returns a representation of the signature of a method id. const Signature GetMethodSignature(const MethodId& method_id) const; // Returns the name of a method id. const char* GetMethodName(const MethodId& method_id) const { return StringDataByIdx(method_id.name_idx_); } // Returns the shorty of a method by its index. const char* GetMethodShorty(uint32_t idx) const { return StringDataByIdx(GetProtoId(GetMethodId(idx).proto_idx_).shorty_idx_); } // Returns the shorty of a method id. const char* GetMethodShorty(const MethodId& method_id) const { return StringDataByIdx(GetProtoId(method_id.proto_idx_).shorty_idx_); } const char* GetMethodShorty(const MethodId& method_id, uint32_t* length) const { // Using the UTF16 length is safe here as shorties are guaranteed to be ASCII characters. return StringDataAndUtf16LengthByIdx(GetProtoId(method_id.proto_idx_).shorty_idx_, length); } // Returns the number of class definitions in the .dex file. uint32_t NumClassDefs() const { DCHECK(header_ != nullptr) << GetLocation(); return header_->class_defs_size_; } // Returns the ClassDef at the specified index. const ClassDef& GetClassDef(uint16_t idx) const { DCHECK_LT(idx, NumClassDefs()) << GetLocation(); return class_defs_[idx]; } uint16_t GetIndexForClassDef(const ClassDef& class_def) const { CHECK_GE(&class_def, class_defs_) << GetLocation(); CHECK_LT(&class_def, class_defs_ + header_->class_defs_size_) << GetLocation(); return &class_def - class_defs_; } // Returns the class descriptor string of a class definition. const char* GetClassDescriptor(const ClassDef& class_def) const { return StringByTypeIdx(class_def.class_idx_); } // Looks up a class definition by its class descriptor. Hash must be // ComputeModifiedUtf8Hash(descriptor). const ClassDef* FindClassDef(const char* descriptor, size_t hash) const; // Looks up a class definition by its type index. const ClassDef* FindClassDef(uint16_t type_idx) const; const TypeList* GetInterfacesList(const ClassDef& class_def) const { if (class_def.interfaces_off_ == 0) { return nullptr; } else { const uint8_t* addr = begin_ + class_def.interfaces_off_; return reinterpret_cast<const TypeList*>(addr); } } // Returns a pointer to the raw memory mapped class_data_item const uint8_t* GetClassData(const ClassDef& class_def) const { if (class_def.class_data_off_ == 0) { return nullptr; } else { return begin_ + class_def.class_data_off_; } } // const CodeItem* GetCodeItem(const uint32_t code_off) const { DCHECK_LT(code_off, size_) << "Code item offset larger then maximum allowed offset"; if (code_off == 0) { return nullptr; // native or abstract method } else { const uint8_t* addr = begin_ + code_off; return reinterpret_cast<const CodeItem*>(addr); } } const char* GetReturnTypeDescriptor(const ProtoId& proto_id) const { return StringByTypeIdx(proto_id.return_type_idx_); } // Returns the number of prototype identifiers in the .dex file. size_t NumProtoIds() const { DCHECK(header_ != nullptr) << GetLocation(); return header_->proto_ids_size_; } // Returns the ProtoId at the specified index. const ProtoId& GetProtoId(uint32_t idx) const { DCHECK_LT(idx, NumProtoIds()) << GetLocation(); return proto_ids_[idx]; } uint16_t GetIndexForProtoId(const ProtoId& proto_id) const { CHECK_GE(&proto_id, proto_ids_) << GetLocation(); CHECK_LT(&proto_id, proto_ids_ + header_->proto_ids_size_) << GetLocation(); return &proto_id - proto_ids_; } // Looks up a proto id for a given return type and signature type list const ProtoId* FindProtoId(uint16_t return_type_idx, const uint16_t* signature_type_idxs, uint32_t signature_length) const; const ProtoId* FindProtoId(uint16_t return_type_idx, const std::vector<uint16_t>& signature_type_idxs) const { return FindProtoId(return_type_idx, &signature_type_idxs[0], signature_type_idxs.size()); } // Given a signature place the type ids into the given vector, returns true on success bool CreateTypeList(const StringPiece& signature, uint16_t* return_type_idx, std::vector<uint16_t>* param_type_idxs) const; // Create a Signature from the given string signature or return Signature::NoSignature if not // possible. const Signature CreateSignature(const StringPiece& signature) const; // Returns the short form method descriptor for the given prototype. const char* GetShorty(uint32_t proto_idx) const { const ProtoId& proto_id = GetProtoId(proto_idx); return StringDataByIdx(proto_id.shorty_idx_); } const TypeList* GetProtoParameters(const ProtoId& proto_id) const { if (proto_id.parameters_off_ == 0) { return nullptr; } else { const uint8_t* addr = begin_ + proto_id.parameters_off_; return reinterpret_cast<const TypeList*>(addr); } } const uint8_t* GetEncodedStaticFieldValuesArray(const ClassDef& class_def) const { if (class_def.static_values_off_ == 0) { return 0; } else { return begin_ + class_def.static_values_off_; } } static const TryItem* GetTryItems(const CodeItem& code_item, uint32_t offset); // Get the base of the encoded data for the given DexCode. static const uint8_t* GetCatchHandlerData(const CodeItem& code_item, uint32_t offset) { const uint8_t* handler_data = reinterpret_cast<const uint8_t*>(GetTryItems(code_item, code_item.tries_size_)); return handler_data + offset; } // Find which try region is associated with the given address (ie dex pc). Returns -1 if none. static int32_t FindTryItem(const CodeItem &code_item, uint32_t address); // Find the handler offset associated with the given address (ie dex pc). Returns -1 if none. static int32_t FindCatchHandlerOffset(const CodeItem &code_item, uint32_t address); // Get the pointer to the start of the debugging data const uint8_t* GetDebugInfoStream(const CodeItem* code_item) const { // Check that the offset is in bounds. // Note that although the specification says that 0 should be used if there // is no debug information, some applications incorrectly use 0xFFFFFFFF. if (code_item->debug_info_off_ == 0 || code_item->debug_info_off_ >= size_) { return nullptr; } else { return begin_ + code_item->debug_info_off_; } } struct PositionInfo { PositionInfo() : address_(0), line_(0), source_file_(nullptr), prologue_end_(false), epilogue_begin_(false) { } uint32_t address_; // In 16-bit code units. uint32_t line_; // Source code line number starting at 1. const char* source_file_; // nullptr if the file from ClassDef still applies. bool prologue_end_; bool epilogue_begin_; }; // Callback for "new position table entry". // Returning true causes the decoder to stop early. typedef bool (*DexDebugNewPositionCb)(void* context, const PositionInfo& entry); struct LocalInfo { LocalInfo() : name_(nullptr), descriptor_(nullptr), signature_(nullptr), start_address_(0), end_address_(0), reg_(0), is_live_(false) { } const char* name_; // E.g., list. It can be nullptr if unknown. const char* descriptor_; // E.g., Ljava/util/LinkedList; const char* signature_; // E.g., java.util.LinkedList<java.lang.Integer> uint32_t start_address_; // PC location where the local is first defined. uint32_t end_address_; // PC location where the local is no longer defined. uint16_t reg_; // Dex register which stores the values. bool is_live_; // Is the local defined and live. }; // Callback for "new locals table entry". typedef void (*DexDebugNewLocalCb)(void* context, const LocalInfo& entry); static bool LineNumForPcCb(void* context, const PositionInfo& entry); const AnnotationsDirectoryItem* GetAnnotationsDirectory(const ClassDef& class_def) const { if (class_def.annotations_off_ == 0) { return nullptr; } else { return reinterpret_cast<const AnnotationsDirectoryItem*>(begin_ + class_def.annotations_off_); } } const AnnotationSetItem* GetClassAnnotationSet(const AnnotationsDirectoryItem* anno_dir) const { if (anno_dir->class_annotations_off_ == 0) { return nullptr; } else { return reinterpret_cast<const AnnotationSetItem*>(begin_ + anno_dir->class_annotations_off_); } } const FieldAnnotationsItem* GetFieldAnnotations(const AnnotationsDirectoryItem* anno_dir) const { if (anno_dir->fields_size_ == 0) { return nullptr; } else { return reinterpret_cast<const FieldAnnotationsItem*>(&anno_dir[1]); } } const MethodAnnotationsItem* GetMethodAnnotations(const AnnotationsDirectoryItem* anno_dir) const { if (anno_dir->methods_size_ == 0) { return nullptr; } else { // Skip past the header and field annotations. const uint8_t* addr = reinterpret_cast<const uint8_t*>(&anno_dir[1]); addr += anno_dir->fields_size_ * sizeof(FieldAnnotationsItem); return reinterpret_cast<const MethodAnnotationsItem*>(addr); } } const ParameterAnnotationsItem* GetParameterAnnotations(const AnnotationsDirectoryItem* anno_dir) const { if (anno_dir->parameters_size_ == 0) { return nullptr; } else { // Skip past the header, field annotations, and method annotations. const uint8_t* addr = reinterpret_cast<const uint8_t*>(&anno_dir[1]); addr += anno_dir->fields_size_ * sizeof(FieldAnnotationsItem); addr += anno_dir->methods_size_ * sizeof(MethodAnnotationsItem); return reinterpret_cast<const ParameterAnnotationsItem*>(addr); } } const AnnotationSetItem* GetFieldAnnotationSetItem(const FieldAnnotationsItem& anno_item) const { uint32_t offset = anno_item.annotations_off_; if (offset == 0) { return nullptr; } else { return reinterpret_cast<const AnnotationSetItem*>(begin_ + offset); } } const AnnotationSetItem* GetMethodAnnotationSetItem(const MethodAnnotationsItem& anno_item) const { uint32_t offset = anno_item.annotations_off_; if (offset == 0) { return nullptr; } else { return reinterpret_cast<const AnnotationSetItem*>(begin_ + offset); } } const AnnotationSetRefList* GetParameterAnnotationSetRefList( const ParameterAnnotationsItem* anno_item) const { uint32_t offset = anno_item->annotations_off_; if (offset == 0) { return nullptr; } return reinterpret_cast<const AnnotationSetRefList*>(begin_ + offset); } const AnnotationItem* GetAnnotationItem(const AnnotationSetItem* set_item, uint32_t index) const { DCHECK_LE(index, set_item->size_); uint32_t offset = set_item->entries_[index]; if (offset == 0) { return nullptr; } else { return reinterpret_cast<const AnnotationItem*>(begin_ + offset); } } const AnnotationSetItem* GetSetRefItemItem(const AnnotationSetRefItem* anno_item) const { uint32_t offset = anno_item->annotations_off_; if (offset == 0) { return nullptr; } return reinterpret_cast<const AnnotationSetItem*>(begin_ + offset); } const AnnotationSetItem* FindAnnotationSetForField(ArtField* field) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* GetAnnotationForField(ArtField* field, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Object>* GetAnnotationsForField(ArtField* field) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::String>* GetSignatureAnnotationForField(ArtField* field) const SHARED_REQUIRES(Locks::mutator_lock_); bool IsFieldAnnotationPresent(ArtField* field, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); const AnnotationSetItem* FindAnnotationSetForMethod(ArtMethod* method) const SHARED_REQUIRES(Locks::mutator_lock_); const ParameterAnnotationsItem* FindAnnotationsItemForMethod(ArtMethod* method) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* GetAnnotationDefaultValue(ArtMethod* method) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* GetAnnotationForMethod(ArtMethod* method, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Object>* GetAnnotationsForMethod(ArtMethod* method) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Class>* GetExceptionTypesForMethod(ArtMethod* method) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Object>* GetParameterAnnotations(ArtMethod* method) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::String>* GetSignatureAnnotationForMethod(ArtMethod* method) const SHARED_REQUIRES(Locks::mutator_lock_); bool IsMethodAnnotationPresent(ArtMethod* method, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); const AnnotationSetItem* FindAnnotationSetForClass(Handle<mirror::Class> klass) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* GetAnnotationForClass(Handle<mirror::Class> klass, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Object>* GetAnnotationsForClass(Handle<mirror::Class> klass) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Class>* GetDeclaredClasses(Handle<mirror::Class> klass) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Class* GetDeclaringClass(Handle<mirror::Class> klass) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Class* GetEnclosingClass(Handle<mirror::Class> klass) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* GetEnclosingMethod(Handle<mirror::Class> klass) const SHARED_REQUIRES(Locks::mutator_lock_); bool GetInnerClass(Handle<mirror::Class> klass, mirror::String** name) const SHARED_REQUIRES(Locks::mutator_lock_); bool GetInnerClassFlags(Handle<mirror::Class> klass, uint32_t* flags) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::String>* GetSignatureAnnotationForClass(Handle<mirror::Class> klass) const SHARED_REQUIRES(Locks::mutator_lock_); bool IsClassAnnotationPresent(Handle<mirror::Class> klass, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* CreateAnnotationMember(Handle<mirror::Class> klass, Handle<mirror::Class> annotation_class, const uint8_t** annotation) const SHARED_REQUIRES(Locks::mutator_lock_); const AnnotationItem* GetAnnotationItemFromAnnotationSet(Handle<mirror::Class> klass, const AnnotationSetItem* annotation_set, uint32_t visibility, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* GetAnnotationObjectFromAnnotationSet(Handle<mirror::Class> klass, const AnnotationSetItem* annotation_set, uint32_t visibility, Handle<mirror::Class> annotation_class) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* GetAnnotationValue(Handle<mirror::Class> klass, const AnnotationItem* annotation_item, const char* annotation_name, Handle<mirror::Class> array_class, uint32_t expected_type) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::String>* GetSignatureValue(Handle<mirror::Class> klass, const AnnotationSetItem* annotation_set) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Class>* GetThrowsValue(Handle<mirror::Class> klass, const AnnotationSetItem* annotation_set) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Object>* ProcessAnnotationSet(Handle<mirror::Class> klass, const AnnotationSetItem* annotation_set, uint32_t visibility) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::ObjectArray<mirror::Object>* ProcessAnnotationSetRefList(Handle<mirror::Class> klass, const AnnotationSetRefList* set_ref_list, uint32_t size) const SHARED_REQUIRES(Locks::mutator_lock_); bool ProcessAnnotationValue(Handle<mirror::Class> klass, const uint8_t** annotation_ptr, AnnotationValue* annotation_value, Handle<mirror::Class> return_class, DexFile::AnnotationResultStyle result_style) const SHARED_REQUIRES(Locks::mutator_lock_); mirror::Object* ProcessEncodedAnnotation(Handle<mirror::Class> klass, const uint8_t** annotation) const SHARED_REQUIRES(Locks::mutator_lock_); const AnnotationItem* SearchAnnotationSet(const AnnotationSetItem* annotation_set, const char* descriptor, uint32_t visibility) const SHARED_REQUIRES(Locks::mutator_lock_); const uint8_t* SearchEncodedAnnotation(const uint8_t* annotation, const char* name) const SHARED_REQUIRES(Locks::mutator_lock_); bool SkipAnnotationValue(const uint8_t** annotation_ptr) const SHARED_REQUIRES(Locks::mutator_lock_); // Debug info opcodes and constants enum { DBG_END_SEQUENCE = 0x00, DBG_ADVANCE_PC = 0x01, DBG_ADVANCE_LINE = 0x02, DBG_START_LOCAL = 0x03, DBG_START_LOCAL_EXTENDED = 0x04, DBG_END_LOCAL = 0x05, DBG_RESTART_LOCAL = 0x06, DBG_SET_PROLOGUE_END = 0x07, DBG_SET_EPILOGUE_BEGIN = 0x08, DBG_SET_FILE = 0x09, DBG_FIRST_SPECIAL = 0x0a, DBG_LINE_BASE = -4, DBG_LINE_RANGE = 15, }; struct LineNumFromPcContext { LineNumFromPcContext(uint32_t address, uint32_t line_num) : address_(address), line_num_(line_num) {} uint32_t address_; uint32_t line_num_; private: DISALLOW_COPY_AND_ASSIGN(LineNumFromPcContext); }; // Determine the source file line number based on the program counter. // "pc" is an offset, in 16-bit units, from the start of the method's code. // // Returns -1 if no match was found (possibly because the source files were // compiled without "-g", so no line number information is present). // Returns -2 for native methods (as expected in exception traces). // // This is used by runtime; therefore use art::Method not art::DexFile::Method. int32_t GetLineNumFromPC(ArtMethod* method, uint32_t rel_pc) const SHARED_REQUIRES(Locks::mutator_lock_); // Returns false if there is no debugging information or if it cannot be decoded. bool DecodeDebugLocalInfo(const CodeItem* code_item, bool is_static, uint32_t method_idx, DexDebugNewLocalCb local_cb, void* context) const; // Returns false if there is no debugging information or if it cannot be decoded. bool DecodeDebugPositionInfo(const CodeItem* code_item, DexDebugNewPositionCb position_cb, void* context) const; const char* GetSourceFile(const ClassDef& class_def) const { if (class_def.source_file_idx_ == 0xffffffff) { return nullptr; } else { return StringDataByIdx(class_def.source_file_idx_); } } int GetPermissions() const; bool IsReadOnly() const; bool EnableWrite() const; bool DisableWrite() const; const uint8_t* Begin() const { return begin_; } size_t Size() const { return size_; } // Return the name of the index-th classes.dex in a multidex zip file. This is classes.dex for // index == 0, and classes{index + 1}.dex else. static std::string GetMultiDexClassesDexName(size_t index); // Return the (possibly synthetic) dex location for a multidex entry. This is dex_location for // index == 0, and dex_location + multi-dex-separator + GetMultiDexClassesDexName(index) else. static std::string GetMultiDexLocation(size_t index, const char* dex_location); // Returns the canonical form of the given dex location. // // There are different flavors of "dex locations" as follows: // the file name of a dex file: // The actual file path that the dex file has on disk. // dex_location: // This acts as a key for the class linker to know which dex file to load. // It may correspond to either an old odex file or a particular dex file // inside an oat file. In the first case it will also match the file name // of the dex file. In the second case (oat) it will include the file name // and possibly some multidex annotation to uniquely identify it. // canonical_dex_location: // the dex_location where it's file name part has been made canonical. static std::string GetDexCanonicalLocation(const char* dex_location); const OatDexFile* GetOatDexFile() const { return oat_dex_file_; } TypeLookupTable* GetTypeLookupTable() const { return lookup_table_.get(); } void CreateTypeLookupTable(uint8_t* storage = nullptr) const; private: // Opens a .dex file static std::unique_ptr<const DexFile> OpenFile(int fd, const char* location, bool verify, std::string* error_msg); // Opens dex files from within a .jar, .zip, or .apk file static bool OpenZip(int fd, const std::string& location, std::string* error_msg, std::vector<std::unique_ptr<const DexFile>>* dex_files); enum class ZipOpenErrorCode { // private kNoError, kEntryNotFound, kExtractToMemoryError, kDexFileError, kMakeReadOnlyError, kVerifyError }; // Opens .dex file from the entry_name in a zip archive. error_code is undefined when non-null // return. static std::unique_ptr<const DexFile> Open(const ZipArchive& zip_archive, const char* entry_name, const std::string& location, std::string* error_msg, ZipOpenErrorCode* error_code); // Opens a .dex file at the given address backed by a MemMap static std::unique_ptr<const DexFile> OpenMemory(const std::string& location, uint32_t location_checksum, MemMap* mem_map, std::string* error_msg); // Opens a .dex file at the given address, optionally backed by a MemMap static std::unique_ptr<const DexFile> OpenMemory(const uint8_t* dex_file, size_t size, const std::string& location, uint32_t location_checksum, MemMap* mem_map, const OatDexFile* oat_dex_file, std::string* error_msg); DexFile(const uint8_t* base, size_t size, const std::string& location, uint32_t location_checksum, MemMap* mem_map, const OatDexFile* oat_dex_file); // Top-level initializer that calls other Init methods. bool Init(std::string* error_msg); // Returns true if the header magic and version numbers are of the expected values. bool CheckMagicAndVersion(std::string* error_msg) const; // Check whether a location denotes a multidex dex file. This is a very simple check: returns // whether the string contains the separator character. static bool IsMultiDexLocation(const char* location); // The base address of the memory mapping. const uint8_t* const begin_; // The size of the underlying memory allocation in bytes. const size_t size_; // Typically the dex file name when available, alternatively some identifying string. // // The ClassLinker will use this to match DexFiles the boot class // path to DexCache::GetLocation when loading from an image. const std::string location_; const uint32_t location_checksum_; // Manages the underlying memory allocation. std::unique_ptr<MemMap> mem_map_; // Points to the header section. const Header* const header_; // Points to the base of the string identifier list. const StringId* const string_ids_; // Points to the base of the type identifier list. const TypeId* const type_ids_; // Points to the base of the field identifier list. const FieldId* const field_ids_; // Points to the base of the method identifier list. const MethodId* const method_ids_; // Points to the base of the prototype identifier list. const ProtoId* const proto_ids_; // Points to the base of the class definition list. const ClassDef* const class_defs_; // If this dex file was loaded from an oat file, oat_dex_file_ contains a // pointer to the OatDexFile it was loaded from. Otherwise oat_dex_file_ is // null. const OatDexFile* oat_dex_file_; mutable std::unique_ptr<TypeLookupTable> lookup_table_; friend class DexFileVerifierTest; ART_FRIEND_TEST(ClassLinkerTest, RegisterDexFileName); // for constructor }; struct DexFileReference { DexFileReference(const DexFile* file, uint32_t idx) : dex_file(file), index(idx) { } const DexFile* dex_file; uint32_t index; }; std::ostream& operator<<(std::ostream& os, const DexFile& dex_file); // Iterate over a dex file's ProtoId's paramters class DexFileParameterIterator { public: DexFileParameterIterator(const DexFile& dex_file, const DexFile::ProtoId& proto_id) : dex_file_(dex_file), size_(0), pos_(0) { type_list_ = dex_file_.GetProtoParameters(proto_id); if (type_list_ != nullptr) { size_ = type_list_->Size(); } } bool HasNext() const { return pos_ < size_; } size_t Size() const { return size_; } void Next() { ++pos_; } uint16_t GetTypeIdx() { return type_list_->GetTypeItem(pos_).type_idx_; } const char* GetDescriptor() { return dex_file_.StringByTypeIdx(GetTypeIdx()); } private: const DexFile& dex_file_; const DexFile::TypeList* type_list_; uint32_t size_; uint32_t pos_; DISALLOW_IMPLICIT_CONSTRUCTORS(DexFileParameterIterator); }; // Abstract the signature of a method. class Signature : public ValueObject { public: std::string ToString() const; static Signature NoSignature() { return Signature(); } bool operator==(const Signature& rhs) const; bool operator!=(const Signature& rhs) const { return !(*this == rhs); } bool operator==(const StringPiece& rhs) const; private: Signature(const DexFile* dex, const DexFile::ProtoId& proto) : dex_file_(dex), proto_id_(&proto) { } Signature() : dex_file_(nullptr), proto_id_(nullptr) { } friend class DexFile; const DexFile* const dex_file_; const DexFile::ProtoId* const proto_id_; }; std::ostream& operator<<(std::ostream& os, const Signature& sig); // Iterate and decode class_data_item class ClassDataItemIterator { public: ClassDataItemIterator(const DexFile& dex_file, const uint8_t* raw_class_data_item) : dex_file_(dex_file), pos_(0), ptr_pos_(raw_class_data_item), last_idx_(0) { ReadClassDataHeader(); if (EndOfInstanceFieldsPos() > 0) { ReadClassDataField(); } else if (EndOfVirtualMethodsPos() > 0) { ReadClassDataMethod(); } } uint32_t NumStaticFields() const { return header_.static_fields_size_; } uint32_t NumInstanceFields() const { return header_.instance_fields_size_; } uint32_t NumDirectMethods() const { return header_.direct_methods_size_; } uint32_t NumVirtualMethods() const { return header_.virtual_methods_size_; } bool HasNextStaticField() const { return pos_ < EndOfStaticFieldsPos(); } bool HasNextInstanceField() const { return pos_ >= EndOfStaticFieldsPos() && pos_ < EndOfInstanceFieldsPos(); } bool HasNextDirectMethod() const { return pos_ >= EndOfInstanceFieldsPos() && pos_ < EndOfDirectMethodsPos(); } bool HasNextVirtualMethod() const { return pos_ >= EndOfDirectMethodsPos() && pos_ < EndOfVirtualMethodsPos(); } bool HasNext() const { return pos_ < EndOfVirtualMethodsPos(); } inline void Next() { pos_++; if (pos_ < EndOfStaticFieldsPos()) { last_idx_ = GetMemberIndex(); ReadClassDataField(); } else if (pos_ == EndOfStaticFieldsPos() && NumInstanceFields() > 0) { last_idx_ = 0; // transition to next array, reset last index ReadClassDataField(); } else if (pos_ < EndOfInstanceFieldsPos()) { last_idx_ = GetMemberIndex(); ReadClassDataField(); } else if (pos_ == EndOfInstanceFieldsPos() && NumDirectMethods() > 0) { last_idx_ = 0; // transition to next array, reset last index ReadClassDataMethod(); } else if (pos_ < EndOfDirectMethodsPos()) { last_idx_ = GetMemberIndex(); ReadClassDataMethod(); } else if (pos_ == EndOfDirectMethodsPos() && NumVirtualMethods() > 0) { last_idx_ = 0; // transition to next array, reset last index ReadClassDataMethod(); } else if (pos_ < EndOfVirtualMethodsPos()) { last_idx_ = GetMemberIndex(); ReadClassDataMethod(); } else { DCHECK(!HasNext()); } } uint32_t GetMemberIndex() const { if (pos_ < EndOfInstanceFieldsPos()) { return last_idx_ + field_.field_idx_delta_; } else { DCHECK_LT(pos_, EndOfVirtualMethodsPos()); return last_idx_ + method_.method_idx_delta_; } } uint32_t GetRawMemberAccessFlags() const { if (pos_ < EndOfInstanceFieldsPos()) { return field_.access_flags_; } else { DCHECK_LT(pos_, EndOfVirtualMethodsPos()); return method_.access_flags_; } } uint32_t GetFieldAccessFlags() const { return GetRawMemberAccessFlags() & kAccValidFieldFlags; } uint32_t GetMethodAccessFlags() const { return GetRawMemberAccessFlags() & kAccValidMethodFlags; } bool MemberIsNative() const { return GetRawMemberAccessFlags() & kAccNative; } bool MemberIsFinal() const { return GetRawMemberAccessFlags() & kAccFinal; } InvokeType GetMethodInvokeType(const DexFile::ClassDef& class_def) const { if (HasNextDirectMethod()) { if ((GetRawMemberAccessFlags() & kAccStatic) != 0) { return kStatic; } else { return kDirect; } } else { DCHECK_EQ(GetRawMemberAccessFlags() & kAccStatic, 0U); if ((class_def.access_flags_ & kAccInterface) != 0) { return kInterface; } else if ((GetRawMemberAccessFlags() & kAccConstructor) != 0) { return kSuper; } else { return kVirtual; } } } const DexFile::CodeItem* GetMethodCodeItem() const { return dex_file_.GetCodeItem(method_.code_off_); } uint32_t GetMethodCodeItemOffset() const { return method_.code_off_; } const uint8_t* DataPointer() const { return ptr_pos_; } const uint8_t* EndDataPointer() const { CHECK(!HasNext()); return ptr_pos_; } private: // A dex file's class_data_item is leb128 encoded, this structure holds a decoded form of the // header for a class_data_item struct ClassDataHeader { uint32_t static_fields_size_; // the number of static fields uint32_t instance_fields_size_; // the number of instance fields uint32_t direct_methods_size_; // the number of direct methods uint32_t virtual_methods_size_; // the number of virtual methods } header_; // Read and decode header from a class_data_item stream into header void ReadClassDataHeader(); uint32_t EndOfStaticFieldsPos() const { return header_.static_fields_size_; } uint32_t EndOfInstanceFieldsPos() const { return EndOfStaticFieldsPos() + header_.instance_fields_size_; } uint32_t EndOfDirectMethodsPos() const { return EndOfInstanceFieldsPos() + header_.direct_methods_size_; } uint32_t EndOfVirtualMethodsPos() const { return EndOfDirectMethodsPos() + header_.virtual_methods_size_; } // A decoded version of the field of a class_data_item struct ClassDataField { uint32_t field_idx_delta_; // delta of index into the field_ids array for FieldId uint32_t access_flags_; // access flags for the field ClassDataField() : field_idx_delta_(0), access_flags_(0) {} private: DISALLOW_COPY_AND_ASSIGN(ClassDataField); }; ClassDataField field_; // Read and decode a field from a class_data_item stream into field void ReadClassDataField(); // A decoded version of the method of a class_data_item struct ClassDataMethod { uint32_t method_idx_delta_; // delta of index into the method_ids array for MethodId uint32_t access_flags_; uint32_t code_off_; ClassDataMethod() : method_idx_delta_(0), access_flags_(0), code_off_(0) {} private: DISALLOW_COPY_AND_ASSIGN(ClassDataMethod); }; ClassDataMethod method_; // Read and decode a method from a class_data_item stream into method void ReadClassDataMethod(); const DexFile& dex_file_; size_t pos_; // integral number of items passed const uint8_t* ptr_pos_; // pointer into stream of class_data_item uint32_t last_idx_; // last read field or method index to apply delta to DISALLOW_IMPLICIT_CONSTRUCTORS(ClassDataItemIterator); }; class EncodedStaticFieldValueIterator { public: // A constructor for static tools. You cannot call // ReadValueToField() for an object created by this. EncodedStaticFieldValueIterator(const DexFile& dex_file, const DexFile::ClassDef& class_def); // A constructor meant to be called from runtime code. EncodedStaticFieldValueIterator(const DexFile& dex_file, Handle<mirror::DexCache>* dex_cache, Handle<mirror::ClassLoader>* class_loader, ClassLinker* linker, const DexFile::ClassDef& class_def) SHARED_REQUIRES(Locks::mutator_lock_); template<bool kTransactionActive> void ReadValueToField(ArtField* field) const SHARED_REQUIRES(Locks::mutator_lock_); bool HasNext() const { return pos_ < array_size_; } void Next(); enum ValueType { kByte = 0x00, kShort = 0x02, kChar = 0x03, kInt = 0x04, kLong = 0x06, kFloat = 0x10, kDouble = 0x11, kString = 0x17, kType = 0x18, kField = 0x19, kMethod = 0x1a, kEnum = 0x1b, kArray = 0x1c, kAnnotation = 0x1d, kNull = 0x1e, kBoolean = 0x1f }; ValueType GetValueType() const { return type_; } const jvalue& GetJavaValue() const { return jval_; } private: EncodedStaticFieldValueIterator(const DexFile& dex_file, Handle<mirror::DexCache>* dex_cache, Handle<mirror::ClassLoader>* class_loader, ClassLinker* linker, const DexFile::ClassDef& class_def, size_t pos, ValueType type); static constexpr uint8_t kEncodedValueTypeMask = 0x1f; // 0b11111 static constexpr uint8_t kEncodedValueArgShift = 5; const DexFile& dex_file_; Handle<mirror::DexCache>* const dex_cache_; // Dex cache to resolve literal objects. Handle<mirror::ClassLoader>* const class_loader_; // ClassLoader to resolve types. ClassLinker* linker_; // Linker to resolve literal objects. size_t array_size_; // Size of array. size_t pos_; // Current position. const uint8_t* ptr_; // Pointer into encoded data array. ValueType type_; // Type of current encoded value. jvalue jval_; // Value of current encoded value. DISALLOW_IMPLICIT_CONSTRUCTORS(EncodedStaticFieldValueIterator); }; std::ostream& operator<<(std::ostream& os, const EncodedStaticFieldValueIterator::ValueType& code); class CatchHandlerIterator { public: CatchHandlerIterator(const DexFile::CodeItem& code_item, uint32_t address); CatchHandlerIterator(const DexFile::CodeItem& code_item, const DexFile::TryItem& try_item); explicit CatchHandlerIterator(const uint8_t* handler_data) { Init(handler_data); } uint16_t GetHandlerTypeIndex() const { return handler_.type_idx_; } uint32_t GetHandlerAddress() const { return handler_.address_; } void Next(); bool HasNext() const { return remaining_count_ != -1 || catch_all_; } // End of this set of catch blocks, convenience method to locate next set of catch blocks const uint8_t* EndDataPointer() const { CHECK(!HasNext()); return current_data_; } private: void Init(const DexFile::CodeItem& code_item, int32_t offset); void Init(const uint8_t* handler_data); struct CatchHandlerItem { uint16_t type_idx_; // type index of the caught exception type uint32_t address_; // handler address } handler_; const uint8_t* current_data_; // the current handler in dex file. int32_t remaining_count_; // number of handlers not read. bool catch_all_; // is there a handler that will catch all exceptions in case // that all typed handler does not match. }; } // namespace art #endif // ART_RUNTIME_DEX_FILE_H_