//===-- CompactUnwindInfo.h -------------------------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef LLDB_SYMBOL_COMPACTUNWINDINFO_H #define LLDB_SYMBOL_COMPACTUNWINDINFO_H #include "lldb/Symbol/ObjectFile.h" #include "lldb/Symbol/UnwindPlan.h" #include "lldb/Utility/DataExtractor.h" #include "lldb/Utility/RangeMap.h" #include "lldb/lldb-private.h" #include #include namespace lldb_private { // Compact Unwind info is an unwind format used on Darwin. The unwind // instructions for typical compiler-generated functions can be expressed in a // 32-bit encoding. The format includes a two-level index so the unwind // information for a function can be found by two binary searches in the // section. It can represent both stack frames that use a frame-pointer // register and frameless functions, on i386/x86_64 for instance. When a // function is too complex to be represented in the compact unwind format, it // calls out to eh_frame unwind instructions. // On Mac OS X / iOS, a function will have either a compact unwind // representation or an eh_frame representation. If lldb is going to benefit // from the compiler's description about saved register locations, it must be // able to read both sources of information. class CompactUnwindInfo { public: CompactUnwindInfo(ObjectFile &objfile, lldb::SectionSP §ion); ~CompactUnwindInfo(); bool GetUnwindPlan(Target &target, Address addr, UnwindPlan &unwind_plan); bool IsValid(const lldb::ProcessSP &process_sp); private: // The top level index entries of the compact unwind info // (internal representation of struct // unwind_info_section_header_index_entry) // There are relatively few of these (one per 500/1000 functions, depending // on format) so creating them on first scan will not be too costly. struct UnwindIndex { uint32_t function_offset = 0; // The offset of the first function covered by // this index uint32_t second_level = 0; // The offset (inside unwind_info sect) to the // second level page for this index // (either UNWIND_SECOND_LEVEL_REGULAR or UNWIND_SECOND_LEVEL_COMPRESSED) uint32_t lsda_array_start = 0; // The offset (inside unwind_info sect) LSDA // array for this index uint32_t lsda_array_end = 0; // The offset to the LSDA array for the NEXT index bool sentinal_entry = false; // There is an empty index at the end which // provides the upper bound of // function addresses that are described UnwindIndex() = default; bool operator<(const CompactUnwindInfo::UnwindIndex &rhs) const { return function_offset < rhs.function_offset; } bool operator==(const CompactUnwindInfo::UnwindIndex &rhs) const { return function_offset == rhs.function_offset; } }; // An internal object used to store the information we retrieve about a // function -- the encoding bits and possibly the LSDA/personality function. struct FunctionInfo { uint32_t encoding = 0; // compact encoding 32-bit value for this function Address lsda_address; // the address of the LSDA data for this function Address personality_ptr_address; // the address where the personality // routine addr can be found uint32_t valid_range_offset_start = 0; // first offset that this encoding is // valid for (start of the function) uint32_t valid_range_offset_end = 0; // the offset of the start of the next function FunctionInfo() = default; }; struct UnwindHeader { uint32_t version; uint32_t common_encodings_array_offset = 0; uint32_t common_encodings_array_count = 0; uint32_t personality_array_offset = 0; uint32_t personality_array_count = 0; UnwindHeader() = default; }; void ScanIndex(const lldb::ProcessSP &process_sp); bool GetCompactUnwindInfoForFunction(Target &target, Address address, FunctionInfo &unwind_info); lldb::offset_t BinarySearchRegularSecondPage(uint32_t entry_page_offset, uint32_t entry_count, uint32_t function_offset, uint32_t *entry_func_start_offset, uint32_t *entry_func_end_offset); uint32_t BinarySearchCompressedSecondPage(uint32_t entry_page_offset, uint32_t entry_count, uint32_t function_offset_to_find, uint32_t function_offset_base, uint32_t *entry_func_start_offset, uint32_t *entry_func_end_offset); uint32_t GetLSDAForFunctionOffset(uint32_t lsda_offset, uint32_t lsda_count, uint32_t function_offset); bool CreateUnwindPlan_x86_64(Target &target, FunctionInfo &function_info, UnwindPlan &unwind_plan, Address pc_or_function_start); bool CreateUnwindPlan_i386(Target &target, FunctionInfo &function_info, UnwindPlan &unwind_plan, Address pc_or_function_start); bool CreateUnwindPlan_arm64(Target &target, FunctionInfo &function_info, UnwindPlan &unwind_plan, Address pc_or_function_start); bool CreateUnwindPlan_armv7(Target &target, FunctionInfo &function_info, UnwindPlan &unwind_plan, Address pc_or_function_start); ObjectFile &m_objfile; lldb::SectionSP m_section_sp; lldb::WritableDataBufferSP m_section_contents_if_encrypted; // if the binary is // encrypted, read the // sect contents // out of live memory and cache them here std::mutex m_mutex; std::vector m_indexes; LazyBool m_indexes_computed; // eLazyBoolYes once we've tried to parse the // unwind info // eLazyBoolNo means we cannot parse the unwind info & should not retry // eLazyBoolCalculate means we haven't tried to parse it yet DataExtractor m_unwindinfo_data; bool m_unwindinfo_data_computed; // true once we've mapped in the unwindinfo // data UnwindHeader m_unwind_header; }; } // namespace lldb_private #endif // LLDB_SYMBOL_COMPACTUNWINDINFO_H