//===-- DynamicRegisterInfo.cpp -------------------------------------------===// // // 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 // //===----------------------------------------------------------------------===// #include "lldb/Target/DynamicRegisterInfo.h" #include "lldb/Core/StreamFile.h" #include "lldb/DataFormatters/FormatManager.h" #include "lldb/Interpreter/OptionArgParser.h" #include "lldb/Utility/ArchSpec.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/RegularExpression.h" #include "lldb/Utility/StringExtractor.h" #include "lldb/Utility/StructuredData.h" using namespace lldb; using namespace lldb_private; DynamicRegisterInfo::DynamicRegisterInfo( const lldb_private::StructuredData::Dictionary &dict, const lldb_private::ArchSpec &arch) { SetRegisterInfo(dict, arch); } DynamicRegisterInfo::DynamicRegisterInfo(DynamicRegisterInfo &&info) { MoveFrom(std::move(info)); } DynamicRegisterInfo & DynamicRegisterInfo::operator=(DynamicRegisterInfo &&info) { MoveFrom(std::move(info)); return *this; } void DynamicRegisterInfo::MoveFrom(DynamicRegisterInfo &&info) { m_regs = std::move(info.m_regs); m_sets = std::move(info.m_sets); m_set_reg_nums = std::move(info.m_set_reg_nums); m_set_names = std::move(info.m_set_names); m_value_regs_map = std::move(info.m_value_regs_map); m_invalidate_regs_map = std::move(info.m_invalidate_regs_map); m_reg_data_byte_size = info.m_reg_data_byte_size; m_finalized = info.m_finalized; if (m_finalized) { const size_t num_sets = m_sets.size(); for (size_t set = 0; set < num_sets; ++set) m_sets[set].registers = m_set_reg_nums[set].data(); } info.Clear(); } llvm::Expected DynamicRegisterInfo::ByteOffsetFromSlice( uint32_t index, llvm::StringRef slice_str, lldb::ByteOrder byte_order) { // Slices use the following format: // REGNAME[MSBIT:LSBIT] // REGNAME - name of the register to grab a slice of // MSBIT - the most significant bit at which the current register value // starts at // LSBIT - the least significant bit at which the current register value // ends at static llvm::Regex g_bitfield_regex( "([A-Za-z_][A-Za-z0-9_]*)\\[([0-9]+):([0-9]+)\\]"); llvm::SmallVector matches; if (!g_bitfield_regex.match(slice_str, &matches)) return llvm::createStringError( llvm::inconvertibleErrorCode(), "failed to match against register bitfield regex (slice: %s)", slice_str.str().c_str()); llvm::StringRef reg_name_str = matches[1]; llvm::StringRef msbit_str = matches[2]; llvm::StringRef lsbit_str = matches[3]; uint32_t msbit; uint32_t lsbit; if (!llvm::to_integer(msbit_str, msbit) || !llvm::to_integer(lsbit_str, lsbit)) return llvm::createStringError( llvm::inconvertibleErrorCode(), "msbit (%s) or lsbit (%s) are invalid", msbit_str.str().c_str(), lsbit_str.str().c_str()); if (msbit <= lsbit) return llvm::createStringError(llvm::inconvertibleErrorCode(), "msbit (%u) must be greater than lsbit (%u)", msbit, lsbit); const uint32_t msbyte = msbit / 8; const uint32_t lsbyte = lsbit / 8; const RegisterInfo *containing_reg_info = GetRegisterInfo(reg_name_str); if (!containing_reg_info) return llvm::createStringError(llvm::inconvertibleErrorCode(), "invalid concrete register \"%s\"", reg_name_str.str().c_str()); const uint32_t max_bit = containing_reg_info->byte_size * 8; if (msbit > max_bit) return llvm::createStringError( llvm::inconvertibleErrorCode(), "msbit (%u) must be less than the bitsize of the register \"%s\" (%u)", msbit, reg_name_str.str().c_str(), max_bit); if (lsbit > max_bit) return llvm::createStringError( llvm::inconvertibleErrorCode(), "lsbit (%u) must be less than the bitsize of the register \"%s\" (%u)", lsbit, reg_name_str.str().c_str(), max_bit); m_invalidate_regs_map[containing_reg_info->kinds[eRegisterKindLLDB]] .push_back(index); m_value_regs_map[index].push_back( containing_reg_info->kinds[eRegisterKindLLDB]); m_invalidate_regs_map[index].push_back( containing_reg_info->kinds[eRegisterKindLLDB]); if (byte_order == eByteOrderLittle) return containing_reg_info->byte_offset + lsbyte; if (byte_order == eByteOrderBig) return containing_reg_info->byte_offset + msbyte; llvm_unreachable("Invalid byte order"); } llvm::Expected DynamicRegisterInfo::ByteOffsetFromComposite( uint32_t index, StructuredData::Array &composite_reg_list, lldb::ByteOrder byte_order) { const size_t num_composite_regs = composite_reg_list.GetSize(); if (num_composite_regs == 0) return llvm::createStringError(llvm::inconvertibleErrorCode(), "\"composite\" list is empty"); uint32_t composite_offset = UINT32_MAX; for (uint32_t composite_idx = 0; composite_idx < num_composite_regs; ++composite_idx) { ConstString composite_reg_name; if (!composite_reg_list.GetItemAtIndexAsString(composite_idx, composite_reg_name, nullptr)) return llvm::createStringError( llvm::inconvertibleErrorCode(), "\"composite\" list value is not a Python string at index %d", composite_idx); const RegisterInfo *composite_reg_info = GetRegisterInfo(composite_reg_name.GetStringRef()); if (!composite_reg_info) return llvm::createStringError( llvm::inconvertibleErrorCode(), "failed to find composite register by name: \"%s\"", composite_reg_name.GetCString()); composite_offset = std::min(composite_offset, composite_reg_info->byte_offset); m_value_regs_map[index].push_back( composite_reg_info->kinds[eRegisterKindLLDB]); m_invalidate_regs_map[composite_reg_info->kinds[eRegisterKindLLDB]] .push_back(index); m_invalidate_regs_map[index].push_back( composite_reg_info->kinds[eRegisterKindLLDB]); } return composite_offset; } llvm::Expected DynamicRegisterInfo::ByteOffsetFromRegInfoDict( uint32_t index, StructuredData::Dictionary ®_info_dict, lldb::ByteOrder byte_order) { uint32_t byte_offset; if (reg_info_dict.GetValueForKeyAsInteger("offset", byte_offset)) return byte_offset; // No offset for this register, see if the register has a value // expression which indicates this register is part of another register. // Value expressions are things like "rax[31:0]" which state that the // current register's value is in a concrete register "rax" in bits 31:0. // If there is a value expression we can calculate the offset llvm::StringRef slice_str; if (reg_info_dict.GetValueForKeyAsString("slice", slice_str, nullptr)) return ByteOffsetFromSlice(index, slice_str, byte_order); StructuredData::Array *composite_reg_list; if (reg_info_dict.GetValueForKeyAsArray("composite", composite_reg_list)) return ByteOffsetFromComposite(index, *composite_reg_list, byte_order); return llvm::createStringError(llvm::inconvertibleErrorCode(), "insufficient data to calculate byte offset"); } size_t DynamicRegisterInfo::SetRegisterInfo(const StructuredData::Dictionary &dict, const ArchSpec &arch) { Log *log = lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_OBJECT); assert(!m_finalized); StructuredData::Array *sets = nullptr; if (dict.GetValueForKeyAsArray("sets", sets)) { const uint32_t num_sets = sets->GetSize(); for (uint32_t i = 0; i < num_sets; ++i) { ConstString set_name; if (sets->GetItemAtIndexAsString(i, set_name) && !set_name.IsEmpty()) { m_sets.push_back({set_name.AsCString(), nullptr, 0, nullptr}); } else { Clear(); printf("error: register sets must have valid names\n"); return 0; } } m_set_reg_nums.resize(m_sets.size()); } StructuredData::Array *regs = nullptr; if (!dict.GetValueForKeyAsArray("registers", regs)) return 0; const ByteOrder byte_order = arch.GetByteOrder(); const uint32_t num_regs = regs->GetSize(); // typedef std::map > // InvalidateNameMap; // InvalidateNameMap invalidate_map; for (uint32_t i = 0; i < num_regs; ++i) { StructuredData::Dictionary *reg_info_dict = nullptr; if (!regs->GetItemAtIndexAsDictionary(i, reg_info_dict)) { Clear(); printf("error: items in the 'registers' array must be dictionaries\n"); regs->DumpToStdout(); return 0; } // { 'name':'rcx' , 'bitsize' : 64, 'offset' : 16, // 'encoding':'uint' , 'format':'hex' , 'set': 0, 'ehframe' : 2, // 'dwarf' : 2, 'generic':'arg4', 'alt-name':'arg4', }, RegisterInfo reg_info; std::vector value_regs; std::vector invalidate_regs; memset(®_info, 0, sizeof(reg_info)); ConstString name_val; ConstString alt_name_val; if (!reg_info_dict->GetValueForKeyAsString("name", name_val, nullptr)) { Clear(); printf("error: registers must have valid names and offsets\n"); reg_info_dict->DumpToStdout(); return 0; } reg_info.name = name_val.GetCString(); reg_info_dict->GetValueForKeyAsString("alt-name", alt_name_val, nullptr); reg_info.alt_name = alt_name_val.GetCString(); llvm::Expected byte_offset = ByteOffsetFromRegInfoDict(i, *reg_info_dict, byte_order); if (byte_offset) reg_info.byte_offset = byte_offset.get(); else { LLDB_LOG_ERROR(log, byte_offset.takeError(), "error while parsing register {1}: {0}", reg_info.name); Clear(); reg_info_dict->DumpToStdout(); return 0; } int64_t bitsize = 0; if (!reg_info_dict->GetValueForKeyAsInteger("bitsize", bitsize)) { Clear(); printf("error: invalid or missing 'bitsize' key/value pair in register " "dictionary\n"); reg_info_dict->DumpToStdout(); return 0; } reg_info.byte_size = bitsize / 8; llvm::StringRef format_str; if (reg_info_dict->GetValueForKeyAsString("format", format_str, nullptr)) { if (OptionArgParser::ToFormat(format_str.str().c_str(), reg_info.format, nullptr) .Fail()) { Clear(); printf("error: invalid 'format' value in register dictionary\n"); reg_info_dict->DumpToStdout(); return 0; } } else { reg_info_dict->GetValueForKeyAsInteger("format", reg_info.format, eFormatHex); } llvm::StringRef encoding_str; if (reg_info_dict->GetValueForKeyAsString("encoding", encoding_str)) reg_info.encoding = Args::StringToEncoding(encoding_str, eEncodingUint); else reg_info_dict->GetValueForKeyAsInteger("encoding", reg_info.encoding, eEncodingUint); size_t set = 0; if (!reg_info_dict->GetValueForKeyAsInteger("set", set, -1) || set >= m_sets.size()) { Clear(); printf("error: invalid 'set' value in register dictionary, valid values " "are 0 - %i\n", (int)set); reg_info_dict->DumpToStdout(); return 0; } // Fill in the register numbers reg_info.kinds[lldb::eRegisterKindLLDB] = i; reg_info.kinds[lldb::eRegisterKindProcessPlugin] = i; uint32_t eh_frame_regno = LLDB_INVALID_REGNUM; reg_info_dict->GetValueForKeyAsInteger("gcc", eh_frame_regno, LLDB_INVALID_REGNUM); if (eh_frame_regno == LLDB_INVALID_REGNUM) reg_info_dict->GetValueForKeyAsInteger("ehframe", eh_frame_regno, LLDB_INVALID_REGNUM); reg_info.kinds[lldb::eRegisterKindEHFrame] = eh_frame_regno; reg_info_dict->GetValueForKeyAsInteger( "dwarf", reg_info.kinds[lldb::eRegisterKindDWARF], LLDB_INVALID_REGNUM); llvm::StringRef generic_str; if (reg_info_dict->GetValueForKeyAsString("generic", generic_str)) reg_info.kinds[lldb::eRegisterKindGeneric] = Args::StringToGenericRegister(generic_str); else reg_info_dict->GetValueForKeyAsInteger( "generic", reg_info.kinds[lldb::eRegisterKindGeneric], LLDB_INVALID_REGNUM); // Check if this register invalidates any other register values when it is // modified StructuredData::Array *invalidate_reg_list = nullptr; if (reg_info_dict->GetValueForKeyAsArray("invalidate-regs", invalidate_reg_list)) { const size_t num_regs = invalidate_reg_list->GetSize(); if (num_regs > 0) { for (uint32_t idx = 0; idx < num_regs; ++idx) { ConstString invalidate_reg_name; uint64_t invalidate_reg_num; if (invalidate_reg_list->GetItemAtIndexAsString( idx, invalidate_reg_name)) { const RegisterInfo *invalidate_reg_info = GetRegisterInfo(invalidate_reg_name.GetStringRef()); if (invalidate_reg_info) { m_invalidate_regs_map[i].push_back( invalidate_reg_info->kinds[eRegisterKindLLDB]); } else { // TODO: print error invalid slice string that doesn't follow the // format printf("error: failed to find a 'invalidate-regs' register for " "\"%s\" while parsing register \"%s\"\n", invalidate_reg_name.GetCString(), reg_info.name); } } else if (invalidate_reg_list->GetItemAtIndexAsInteger( idx, invalidate_reg_num)) { if (invalidate_reg_num != UINT64_MAX) m_invalidate_regs_map[i].push_back(invalidate_reg_num); else printf("error: 'invalidate-regs' list value wasn't a valid " "integer\n"); } else { printf("error: 'invalidate-regs' list value wasn't a python string " "or integer\n"); } } } else { printf("error: 'invalidate-regs' contained an empty list\n"); } } // Calculate the register offset const size_t end_reg_offset = reg_info.byte_offset + reg_info.byte_size; if (m_reg_data_byte_size < end_reg_offset) m_reg_data_byte_size = end_reg_offset; m_regs.push_back(reg_info); m_set_reg_nums[set].push_back(i); } Finalize(arch); return m_regs.size(); } size_t DynamicRegisterInfo::SetRegisterInfo( std::vector &®s, const ArchSpec &arch) { assert(!m_finalized); for (auto it : llvm::enumerate(regs)) { uint32_t local_regnum = it.index(); const DynamicRegisterInfo::Register ® = it.value(); assert(reg.name); assert(reg.set_name); if (!reg.value_regs.empty()) m_value_regs_map[local_regnum] = std::move(reg.value_regs); if (!reg.invalidate_regs.empty()) m_invalidate_regs_map[local_regnum] = std::move(reg.invalidate_regs); if (reg.value_reg_offset != 0) { assert(reg.value_regs.size() == 1); m_value_reg_offset_map[local_regnum] = reg.value_reg_offset; } struct RegisterInfo reg_info { reg.name.AsCString(), reg.alt_name.AsCString(), reg.byte_size, reg.byte_offset, reg.encoding, reg.format, {reg.regnum_ehframe, reg.regnum_dwarf, reg.regnum_generic, reg.regnum_remote, local_regnum}, // value_regs and invalidate_regs are filled by Finalize() nullptr, nullptr }; m_regs.push_back(reg_info); uint32_t set = GetRegisterSetIndexByName(reg.set_name, true); assert(set < m_sets.size()); assert(set < m_set_reg_nums.size()); assert(set < m_set_names.size()); m_set_reg_nums[set].push_back(local_regnum); }; Finalize(arch); return m_regs.size(); } void DynamicRegisterInfo::Finalize(const ArchSpec &arch) { if (m_finalized) return; m_finalized = true; const size_t num_sets = m_sets.size(); for (size_t set = 0; set < num_sets; ++set) { assert(m_sets.size() == m_set_reg_nums.size()); m_sets[set].num_registers = m_set_reg_nums[set].size(); m_sets[set].registers = m_set_reg_nums[set].data(); } // make sure value_regs are terminated with LLDB_INVALID_REGNUM for (reg_to_regs_map::iterator pos = m_value_regs_map.begin(), end = m_value_regs_map.end(); pos != end; ++pos) { if (pos->second.back() != LLDB_INVALID_REGNUM) pos->second.push_back(LLDB_INVALID_REGNUM); } // Now update all value_regs with each register info as needed const size_t num_regs = m_regs.size(); for (size_t i = 0; i < num_regs; ++i) { if (m_value_regs_map.find(i) != m_value_regs_map.end()) m_regs[i].value_regs = m_value_regs_map[i].data(); else m_regs[i].value_regs = nullptr; } // Expand all invalidation dependencies for (reg_to_regs_map::iterator pos = m_invalidate_regs_map.begin(), end = m_invalidate_regs_map.end(); pos != end; ++pos) { const uint32_t reg_num = pos->first; if (m_regs[reg_num].value_regs) { reg_num_collection extra_invalid_regs; for (const uint32_t invalidate_reg_num : pos->second) { reg_to_regs_map::iterator invalidate_pos = m_invalidate_regs_map.find(invalidate_reg_num); if (invalidate_pos != m_invalidate_regs_map.end()) { for (const uint32_t concrete_invalidate_reg_num : invalidate_pos->second) { if (concrete_invalidate_reg_num != reg_num) extra_invalid_regs.push_back(concrete_invalidate_reg_num); } } } pos->second.insert(pos->second.end(), extra_invalid_regs.begin(), extra_invalid_regs.end()); } } // sort and unique all invalidate registers and make sure each is terminated // with LLDB_INVALID_REGNUM for (reg_to_regs_map::iterator pos = m_invalidate_regs_map.begin(), end = m_invalidate_regs_map.end(); pos != end; ++pos) { if (pos->second.size() > 1) { llvm::sort(pos->second.begin(), pos->second.end()); reg_num_collection::iterator unique_end = std::unique(pos->second.begin(), pos->second.end()); if (unique_end != pos->second.end()) pos->second.erase(unique_end, pos->second.end()); } assert(!pos->second.empty()); if (pos->second.back() != LLDB_INVALID_REGNUM) pos->second.push_back(LLDB_INVALID_REGNUM); } // Now update all invalidate_regs with each register info as needed for (size_t i = 0; i < num_regs; ++i) { if (m_invalidate_regs_map.find(i) != m_invalidate_regs_map.end()) m_regs[i].invalidate_regs = m_invalidate_regs_map[i].data(); else m_regs[i].invalidate_regs = nullptr; } // Check if we need to automatically set the generic registers in case they // weren't set bool generic_regs_specified = false; for (const auto ® : m_regs) { if (reg.kinds[eRegisterKindGeneric] != LLDB_INVALID_REGNUM) { generic_regs_specified = true; break; } } if (!generic_regs_specified) { switch (arch.GetMachine()) { case llvm::Triple::aarch64: case llvm::Triple::aarch64_32: case llvm::Triple::aarch64_be: for (auto ® : m_regs) { if (strcmp(reg.name, "pc") == 0) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_PC; else if ((strcmp(reg.name, "fp") == 0) || (strcmp(reg.name, "x29") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FP; else if ((strcmp(reg.name, "lr") == 0) || (strcmp(reg.name, "x30") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_RA; else if ((strcmp(reg.name, "sp") == 0) || (strcmp(reg.name, "x31") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_SP; else if (strcmp(reg.name, "cpsr") == 0) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FLAGS; } break; case llvm::Triple::arm: case llvm::Triple::armeb: case llvm::Triple::thumb: case llvm::Triple::thumbeb: for (auto ® : m_regs) { if ((strcmp(reg.name, "pc") == 0) || (strcmp(reg.name, "r15") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_PC; else if ((strcmp(reg.name, "sp") == 0) || (strcmp(reg.name, "r13") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_SP; else if ((strcmp(reg.name, "lr") == 0) || (strcmp(reg.name, "r14") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_RA; else if ((strcmp(reg.name, "r7") == 0) && arch.GetTriple().getVendor() == llvm::Triple::Apple) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FP; else if ((strcmp(reg.name, "r11") == 0) && arch.GetTriple().getVendor() != llvm::Triple::Apple) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FP; else if (strcmp(reg.name, "fp") == 0) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FP; else if (strcmp(reg.name, "cpsr") == 0) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FLAGS; } break; case llvm::Triple::x86: for (auto ® : m_regs) { if ((strcmp(reg.name, "eip") == 0) || (strcmp(reg.name, "pc") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_PC; else if ((strcmp(reg.name, "esp") == 0) || (strcmp(reg.name, "sp") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_SP; else if ((strcmp(reg.name, "ebp") == 0) || (strcmp(reg.name, "fp") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FP; else if ((strcmp(reg.name, "eflags") == 0) || (strcmp(reg.name, "flags") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FLAGS; } break; case llvm::Triple::x86_64: for (auto ® : m_regs) { if ((strcmp(reg.name, "rip") == 0) || (strcmp(reg.name, "pc") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_PC; else if ((strcmp(reg.name, "rsp") == 0) || (strcmp(reg.name, "sp") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_SP; else if ((strcmp(reg.name, "rbp") == 0) || (strcmp(reg.name, "fp") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FP; else if ((strcmp(reg.name, "rflags") == 0) || (strcmp(reg.name, "eflags") == 0) || (strcmp(reg.name, "flags") == 0)) reg.kinds[eRegisterKindGeneric] = LLDB_REGNUM_GENERIC_FLAGS; } break; default: break; } } // At this stage call ConfigureOffsets to calculate register offsets for // targets supporting dynamic offset calculation. It also calculates // total byte size of register data. ConfigureOffsets(); // Check if register info is reconfigurable // AArch64 SVE register set has configurable register sizes if (arch.GetTriple().isAArch64()) { for (const auto ® : m_regs) { if (strcmp(reg.name, "vg") == 0) { m_is_reconfigurable = true; break; } } } } void DynamicRegisterInfo::ConfigureOffsets() { // We are going to create a map between remote (eRegisterKindProcessPlugin) // and local (eRegisterKindLLDB) register numbers. This map will give us // remote register numbers in increasing order for offset calculation. std::map remote_to_local_regnum_map; for (const auto ® : m_regs) remote_to_local_regnum_map[reg.kinds[eRegisterKindProcessPlugin]] = reg.kinds[eRegisterKindLLDB]; // At this stage we manually calculate g/G packet offsets of all primary // registers, only if target XML or qRegisterInfo packet did not send // an offset explicitly. uint32_t reg_offset = 0; for (auto const ®num_pair : remote_to_local_regnum_map) { if (m_regs[regnum_pair.second].byte_offset == LLDB_INVALID_INDEX32 && m_regs[regnum_pair.second].value_regs == nullptr) { m_regs[regnum_pair.second].byte_offset = reg_offset; reg_offset = m_regs[regnum_pair.second].byte_offset + m_regs[regnum_pair.second].byte_size; } } // Now update all value_regs with each register info as needed for (auto ® : m_regs) { if (reg.value_regs != nullptr) { // Assign a valid offset to all pseudo registers that have only a single // parent register in value_regs list, if not assigned by stub. Pseudo // registers with value_regs list populated will share same offset as // that of their corresponding parent register. if (reg.byte_offset == LLDB_INVALID_INDEX32) { uint32_t value_regnum = reg.value_regs[0]; if (value_regnum != LLDB_INVALID_INDEX32 && reg.value_regs[1] == LLDB_INVALID_INDEX32) { reg.byte_offset = GetRegisterInfoAtIndex(value_regnum)->byte_offset; auto it = m_value_reg_offset_map.find(reg.kinds[eRegisterKindLLDB]); if (it != m_value_reg_offset_map.end()) reg.byte_offset += it->second; } } } reg_offset = reg.byte_offset + reg.byte_size; if (m_reg_data_byte_size < reg_offset) m_reg_data_byte_size = reg_offset; } } bool DynamicRegisterInfo::IsReconfigurable() { return m_is_reconfigurable; } size_t DynamicRegisterInfo::GetNumRegisters() const { return m_regs.size(); } size_t DynamicRegisterInfo::GetNumRegisterSets() const { return m_sets.size(); } size_t DynamicRegisterInfo::GetRegisterDataByteSize() const { return m_reg_data_byte_size; } const RegisterInfo * DynamicRegisterInfo::GetRegisterInfoAtIndex(uint32_t i) const { if (i < m_regs.size()) return &m_regs[i]; return nullptr; } const RegisterInfo *DynamicRegisterInfo::GetRegisterInfo(uint32_t kind, uint32_t num) const { uint32_t reg_index = ConvertRegisterKindToRegisterNumber(kind, num); if (reg_index != LLDB_INVALID_REGNUM) return &m_regs[reg_index]; return nullptr; } const RegisterSet *DynamicRegisterInfo::GetRegisterSet(uint32_t i) const { if (i < m_sets.size()) return &m_sets[i]; return nullptr; } uint32_t DynamicRegisterInfo::GetRegisterSetIndexByName(const ConstString &set_name, bool can_create) { name_collection::iterator pos, end = m_set_names.end(); for (pos = m_set_names.begin(); pos != end; ++pos) { if (*pos == set_name) return std::distance(m_set_names.begin(), pos); } m_set_names.push_back(set_name); m_set_reg_nums.resize(m_set_reg_nums.size() + 1); RegisterSet new_set = {set_name.AsCString(), nullptr, 0, nullptr}; m_sets.push_back(new_set); return m_sets.size() - 1; } uint32_t DynamicRegisterInfo::ConvertRegisterKindToRegisterNumber(uint32_t kind, uint32_t num) const { reg_collection::const_iterator pos, end = m_regs.end(); for (pos = m_regs.begin(); pos != end; ++pos) { if (pos->kinds[kind] == num) return std::distance(m_regs.begin(), pos); } return LLDB_INVALID_REGNUM; } void DynamicRegisterInfo::Clear() { m_regs.clear(); m_sets.clear(); m_set_reg_nums.clear(); m_set_names.clear(); m_value_regs_map.clear(); m_invalidate_regs_map.clear(); m_reg_data_byte_size = 0; m_finalized = false; } void DynamicRegisterInfo::Dump() const { StreamFile s(stdout, false); const size_t num_regs = m_regs.size(); s.Printf("%p: DynamicRegisterInfo contains %" PRIu64 " registers:\n", static_cast(this), static_cast(num_regs)); for (size_t i = 0; i < num_regs; ++i) { s.Printf("[%3" PRIu64 "] name = %-10s", (uint64_t)i, m_regs[i].name); s.Printf(", size = %2u, offset = %4u, encoding = %u, format = %-10s", m_regs[i].byte_size, m_regs[i].byte_offset, m_regs[i].encoding, FormatManager::GetFormatAsCString(m_regs[i].format)); if (m_regs[i].kinds[eRegisterKindProcessPlugin] != LLDB_INVALID_REGNUM) s.Printf(", process plugin = %3u", m_regs[i].kinds[eRegisterKindProcessPlugin]); if (m_regs[i].kinds[eRegisterKindDWARF] != LLDB_INVALID_REGNUM) s.Printf(", dwarf = %3u", m_regs[i].kinds[eRegisterKindDWARF]); if (m_regs[i].kinds[eRegisterKindEHFrame] != LLDB_INVALID_REGNUM) s.Printf(", ehframe = %3u", m_regs[i].kinds[eRegisterKindEHFrame]); if (m_regs[i].kinds[eRegisterKindGeneric] != LLDB_INVALID_REGNUM) s.Printf(", generic = %3u", m_regs[i].kinds[eRegisterKindGeneric]); if (m_regs[i].alt_name) s.Printf(", alt-name = %s", m_regs[i].alt_name); if (m_regs[i].value_regs) { s.Printf(", value_regs = [ "); for (size_t j = 0; m_regs[i].value_regs[j] != LLDB_INVALID_REGNUM; ++j) { s.Printf("%s ", m_regs[m_regs[i].value_regs[j]].name); } s.Printf("]"); } if (m_regs[i].invalidate_regs) { s.Printf(", invalidate_regs = [ "); for (size_t j = 0; m_regs[i].invalidate_regs[j] != LLDB_INVALID_REGNUM; ++j) { s.Printf("%s ", m_regs[m_regs[i].invalidate_regs[j]].name); } s.Printf("]"); } s.EOL(); } const size_t num_sets = m_sets.size(); s.Printf("%p: DynamicRegisterInfo contains %" PRIu64 " register sets:\n", static_cast(this), static_cast(num_sets)); for (size_t i = 0; i < num_sets; ++i) { s.Printf("set[%" PRIu64 "] name = %s, regs = [", (uint64_t)i, m_sets[i].name); for (size_t idx = 0; idx < m_sets[i].num_registers; ++idx) { s.Printf("%s ", m_regs[m_sets[i].registers[idx]].name); } s.Printf("]\n"); } } const lldb_private::RegisterInfo * DynamicRegisterInfo::GetRegisterInfo(llvm::StringRef reg_name) const { for (auto ®_info : m_regs) if (reg_info.name == reg_name) return ®_info; return nullptr; } void lldb_private::addSupplementaryRegister( std::vector ®s, DynamicRegisterInfo::Register new_reg_info) { assert(!new_reg_info.value_regs.empty()); const uint32_t reg_num = regs.size(); regs.push_back(new_reg_info); std::map> new_invalidates; for (uint32_t value_reg : new_reg_info.value_regs) { // copy value_regs to invalidate_regs new_invalidates[reg_num].push_back(value_reg); // copy invalidate_regs from the parent register llvm::append_range(new_invalidates[reg_num], regs[value_reg].invalidate_regs); // add reverse invalidate entries for (uint32_t x : new_invalidates[reg_num]) new_invalidates[x].push_back(reg_num); } for (const auto &x : new_invalidates) llvm::append_range(regs[x.first].invalidate_regs, x.second); }