bool Section::ResolveContainedAddress (addr_t offset, Address &so_addr) const { const uint32_t num_children = m_children.GetSize(); if (num_children > 0) { for (uint32_t i=0; i<num_children; i++) { Section* child_section = m_children.GetSectionAtIndex (i).get(); addr_t child_offset = child_section->GetOffset(); if (child_offset <= offset && offset - child_offset < child_section->GetByteSize()) return child_section->ResolveContainedAddress (offset - child_offset, so_addr); } } SectionSP linked_section_sp (m_linked_section_wp.lock()); if (linked_section_sp) { so_addr.SetOffset(m_linked_offset + offset); so_addr.SetSection(linked_section_sp); } else { so_addr.SetOffset(offset); so_addr.SetSection(const_cast<Section *>(this)->shared_from_this()); #ifdef LLDB_CONFIGURATION_DEBUG // For debug builds, ensure that there are no orphaned (i.e., moduleless) sections. assert(GetModule().get()); #endif } return true; }
bool Section::ResolveContainedAddress (addr_t offset, Address &so_addr) const { const uint32_t num_children = m_children.GetSize(); if (num_children > 0) { for (uint32_t i=0; i<num_children; i++) { Section* child_section = m_children.GetSectionAtIndex (i).get(); addr_t child_offset = child_section->GetOffset(); if (child_offset <= offset && offset - child_offset < child_section->GetByteSize()) return child_section->ResolveContainedAddress (offset - child_offset, so_addr); } } if (m_linked_section) { so_addr.SetOffset(m_linked_offset + offset); so_addr.SetSection(m_linked_section); } else { so_addr.SetOffset(offset); so_addr.SetSection(this); } return true; }
//TODO: Need more work bool Instruction::GetOperandReference(Database const& rDatabase, u8 Oprd, Address const& rAddrSrc, Address& rAddrDst) const { medusa::Operand const* pOprd = Operand(Oprd); TOffset Offset = 0x0; rAddrDst = rAddrSrc; // XXX: Should never happen if (pOprd == NULL) return false; if (pOprd->GetType() & O_NO_REF) return false; if ((pOprd->GetType() & O_REL) || ((pOprd->GetType() & O_REG_PC_REL) && (pOprd->GetType() & O_MEM))) { switch (pOprd->GetType() & DS_MASK) { case DS_8BIT: Offset = static_cast<s8> (pOprd->GetValue()) + GetLength(); break; case DS_16BIT: Offset = static_cast<s16>(pOprd->GetValue()) + GetLength(); break; case DS_32BIT: Offset = static_cast<s32>(pOprd->GetValue()) + GetLength(); break; case DS_64BIT: Offset = static_cast<s64>(pOprd->GetValue()) + GetLength(); break; default: Offset = pOprd->GetValue() + GetLength(); } rAddrDst = rAddrSrc + Offset; return true; } else if ((pOprd->GetType() & O_ABS) || (pOprd->GetType() & O_IMM) || (pOprd->GetType() & O_DISP)) { switch (pOprd->GetType() & DS_MASK) { case DS_8BIT: rAddrDst.SetOffset(static_cast<s8> (pOprd->GetValue())); break; case DS_16BIT: rAddrDst.SetOffset(static_cast<s16>(pOprd->GetValue())); break; case DS_32BIT: rAddrDst.SetOffset(static_cast<s32>(pOprd->GetValue())); break; case DS_64BIT: rAddrDst.SetOffset(static_cast<s64>(pOprd->GetValue())); break; default: rAddrDst.SetOffset(pOprd->GetValue()); } return true; } else if ((pOprd->GetType() & O_MEM)) { if (pOprd->GetType() & O_REG_PC_REL) Offset += rAddrSrc.GetOffset(); switch (pOprd->GetType() & DS_MASK) { case DS_8BIT: Offset += static_cast<s8> (pOprd->GetValue()) + GetLength(); break; case DS_16BIT: Offset += static_cast<s16>(pOprd->GetValue()) + GetLength(); break; case DS_32BIT: Offset += static_cast<s32>(pOprd->GetValue()) + GetLength(); break; case DS_64BIT: Offset += static_cast<s64>(pOprd->GetValue()) + GetLength(); break; default: Offset += pOprd->GetValue() + GetLength(); } rAddrDst.SetOffset(Offset); TOffset RawOffset; MemoryArea const* pMemArea = rDatabase.GetMemoryArea(rAddrDst); if (pMemArea == nullptr) return false; if (!pMemArea->Convert(Offset, RawOffset)) return false; BinaryStream const& rBinStrm = pMemArea->GetBinaryStream(); u64 ReadOffset = 0x0; try { switch (pOprd->GetType() & MS_MASK) { case MS_8BIT: rBinStrm.Read(RawOffset, ReadOffset); ReadOffset &= 0xff; break; case MS_16BIT: rBinStrm.Read(RawOffset, ReadOffset); ReadOffset &= 0xffff; break; case MS_32BIT: rBinStrm.Read(RawOffset, ReadOffset); ReadOffset &= 0xffffffff; break; case MS_64BIT: rBinStrm.Read(RawOffset, ReadOffset); break; default: return false; } } catch(Exception&) { return false; } rAddrDst.SetOffset(ReadOffset); return true; } return false; }
Address VirtualMemoryArea::MakeAddress(TOffset Offset) const { Address Addr = m_VirtualBase; Addr.SetOffset(Offset); return Addr; }
bool ItaniumABILanguageRuntime::GetDynamicTypeAndAddress (ValueObject &in_value, lldb::DynamicValueType use_dynamic, TypeAndOrName &class_type_or_name, Address &dynamic_address) { // For Itanium, if the type has a vtable pointer in the object, it will be at offset 0 // in the object. That will point to the "address point" within the vtable (not the beginning of the // vtable.) We can then look up the symbol containing this "address point" and that symbol's name // demangled will contain the full class name. // The second pointer above the "address point" is the "offset_to_top". We'll use that to get the // start of the value object which holds the dynamic type. // // Only a pointer or reference type can have a different dynamic and static type: if (CouldHaveDynamicValue (in_value)) { // FIXME: Can we get the Clang Type and ask it if the thing is really virtual? That would avoid false positives, // at the cost of not looking for the dynamic type of objects if DWARF->Clang gets it wrong. // First job, pull out the address at 0 offset from the object. AddressType address_type; lldb::addr_t original_ptr = in_value.GetPointerValue(&address_type); if (original_ptr == LLDB_INVALID_ADDRESS) return false; Target *target = in_value.GetUpdatePoint().GetTargetSP().get(); Process *process = in_value.GetUpdatePoint().GetProcessSP().get(); char memory_buffer[16]; DataExtractor data(memory_buffer, sizeof(memory_buffer), process->GetByteOrder(), process->GetAddressByteSize()); size_t address_byte_size = process->GetAddressByteSize(); Error error; size_t bytes_read = process->ReadMemory (original_ptr, memory_buffer, address_byte_size, error); if (!error.Success() || (bytes_read != address_byte_size)) { return false; } uint32_t offset_ptr = 0; lldb::addr_t vtable_address_point = data.GetAddress (&offset_ptr); if (offset_ptr == 0) return false; // Now find the symbol that contains this address: SymbolContext sc; Address address_point_address; if (target && !target->GetSectionLoadList().IsEmpty()) { if (target->GetSectionLoadList().ResolveLoadAddress (vtable_address_point, address_point_address)) { target->GetImages().ResolveSymbolContextForAddress (address_point_address, eSymbolContextSymbol, sc); Symbol *symbol = sc.symbol; if (symbol != NULL) { const char *name = symbol->GetMangled().GetDemangledName().AsCString(); if (strstr(name, vtable_demangled_prefix) == name) { // We are a C++ class, that's good. Get the class name and look it up: const char *class_name = name + strlen(vtable_demangled_prefix); class_type_or_name.SetName (class_name); TypeList class_types; uint32_t num_matches = target->GetImages().FindTypes (sc, ConstString(class_name), true, UINT32_MAX, class_types); if (num_matches == 1) { class_type_or_name.SetTypeSP(class_types.GetTypeAtIndex(0)); } else if (num_matches > 1) { for (size_t i = 0; i < num_matches; i++) { lldb::TypeSP this_type(class_types.GetTypeAtIndex(i)); if (this_type) { if (ClangASTContext::IsCXXClassType(this_type->GetClangFullType())) { // There can only be one type with a given name, // so we've just found duplicate definitions, and this // one will do as well as any other. // We don't consider something to have a dynamic type if // it is the same as the static type. So compare against // the value we were handed: clang::ASTContext *in_ast_ctx = in_value.GetClangAST (); clang::ASTContext *this_ast_ctx = this_type->GetClangAST (); if (in_ast_ctx != this_ast_ctx || !ClangASTContext::AreTypesSame (in_ast_ctx, in_value.GetClangType(), this_type->GetClangFullType())) { class_type_or_name.SetTypeSP (this_type); return true; } return false; } } } } else return false; // The offset_to_top is two pointers above the address. Address offset_to_top_address = address_point_address; int64_t slide = -2 * ((int64_t) target->GetArchitecture().GetAddressByteSize()); offset_to_top_address.Slide (slide); Error error; lldb::addr_t offset_to_top_location = offset_to_top_address.GetLoadAddress(target); size_t bytes_read = process->ReadMemory (offset_to_top_location, memory_buffer, address_byte_size, error); if (!error.Success() || (bytes_read != address_byte_size)) { return false; } offset_ptr = 0; int64_t offset_to_top = data.GetMaxS64(&offset_ptr, process->GetAddressByteSize()); // So the dynamic type is a value that starts at offset_to_top // above the original address. lldb::addr_t dynamic_addr = original_ptr + offset_to_top; if (!target->GetSectionLoadList().ResolveLoadAddress (dynamic_addr, dynamic_address)) { dynamic_address.SetOffset(dynamic_addr); dynamic_address.SetSection(NULL); } return true; } } } } } return false; }