int64_t Function::stackDeltaConcrete() const { BaseSemantics::SValuePtr v = stackDelta(); if (v && v->is_number() && v->get_width() <= 64) return IntegerOps::signExtend2<uint64_t>(v->get_number(), v->get_width(), 64); return SgAsmInstruction::INVALID_STACK_DELTA; }
BinaryAnalysis::Disassembler::AddressSet SgAsmX86Instruction::getSuccessors(const std::vector<SgAsmInstruction*>& insns, bool *complete, const MemoryMap::Ptr &initial_memory) { Stream debug(mlog[DEBUG]); using namespace Rose::BinaryAnalysis::InstructionSemantics2; if (debug) { debug <<"SgAsmX86Instruction::getSuccessors(" <<StringUtility::addrToString(insns.front()->get_address()) <<" for " <<insns.size() <<" instruction" <<(1==insns.size()?"":"s") <<"):" <<"\n"; } BinaryAnalysis::Disassembler::AddressSet successors = SgAsmInstruction::getSuccessors(insns, complete); /* If we couldn't determine all the successors, or a cursory analysis couldn't narrow it down to a single successor then * we'll do a more thorough analysis now. In the case where the cursory analysis returned a complete set containing two * successors, a thorough analysis might be able to narrow it down to a single successor. We should not make special * assumptions about CALL and FARCALL instructions -- their only successor is the specified address operand. */ if (!*complete || successors.size()>1) { const RegisterDictionary *regdict; if (SgAsmInterpretation *interp = SageInterface::getEnclosingNode<SgAsmInterpretation>(this)) { regdict = RegisterDictionary::dictionary_for_isa(interp); } else { switch (get_baseSize()) { case x86_insnsize_16: regdict = RegisterDictionary::dictionary_i286(); break; case x86_insnsize_32: regdict = RegisterDictionary::dictionary_pentium4(); break; case x86_insnsize_64: regdict = RegisterDictionary::dictionary_amd64(); break; default: ASSERT_not_reachable("invalid x86 instruction size"); } } const RegisterDescriptor IP = regdict->findLargestRegister(x86_regclass_ip, 0); PartialSymbolicSemantics::RiscOperatorsPtr ops = PartialSymbolicSemantics::RiscOperators::instance(regdict); ops->set_memory_map(initial_memory); BaseSemantics::DispatcherPtr cpu = DispatcherX86::instance(ops, IP.get_nbits(), regdict); try { BOOST_FOREACH (SgAsmInstruction *insn, insns) { cpu->processInstruction(insn); SAWYER_MESG(debug) <<" state after " <<insn->toString() <<"\n" <<*ops; } BaseSemantics::SValuePtr ip = ops->readRegister(IP); if (ip->is_number()) { successors.clear(); successors.insert(ip->get_number()); *complete = true; } } catch(const BaseSemantics::Exception &e) {
/* Analyze a single interpretation a block at a time */ static void analyze_interp(SgAsmInterpretation *interp) { /* Get the set of all instructions except instructions that are part of left-over blocks. */ struct AllInstructions: public SgSimpleProcessing, public std::map<rose_addr_t, SgAsmX86Instruction*> { void visit(SgNode *node) { SgAsmX86Instruction *insn = isSgAsmX86Instruction(node); SgAsmFunction *func = SageInterface::getEnclosingNode<SgAsmFunction>(insn); if (func && 0==(func->get_reason() & SgAsmFunction::FUNC_LEFTOVERS)) insert(std::make_pair(insn->get_address(), insn)); } } insns; insns.traverse(interp, postorder); while (!insns.empty()) { std::cout <<"=====================================================================================\n" <<"=== Starting a new basic block ===\n" <<"=====================================================================================\n"; AllInstructions::iterator si = insns.begin(); SgAsmX86Instruction *insn = si->second; insns.erase(si); BaseSemantics::RiscOperatorsPtr operators = make_ops(); BaseSemantics::Formatter formatter; formatter.set_suppress_initial_values(); formatter.set_show_latest_writers(do_usedef); BaseSemantics::DispatcherPtr dispatcher; if (do_trace) { // Enable RiscOperators tracing, but turn off a bunch of info that makes comparisons with a known good answer // difficult. Sawyer::Message::PrefixPtr prefix = Sawyer::Message::Prefix::instance(); prefix->showProgramName(false); prefix->showThreadId(false); prefix->showElapsedTime(false); prefix->showFacilityName(Sawyer::Message::Prefix::NEVER); prefix->showImportance(false); Sawyer::Message::UnformattedSinkPtr sink = Sawyer::Message::StreamSink::instance(std::cout); sink->prefix(prefix); sink->defaultPropertiesNS().useColor = false; TraceSemantics::RiscOperatorsPtr trace = TraceSemantics::RiscOperators::instance(operators); trace->stream().destination(sink); trace->stream().enable(); dispatcher = DispatcherX86::instance(trace, 32); } else { dispatcher = DispatcherX86::instance(operators, 32); } operators->set_solver(make_solver()); // The fpstatus_top register must have a concrete value if we'll use the x86 floating-point stack (e.g., st(0)) if (const RegisterDescriptor *REG_FPSTATUS_TOP = regdict->lookup("fpstatus_top")) { BaseSemantics::SValuePtr st_top = operators->number_(REG_FPSTATUS_TOP->get_nbits(), 0); operators->writeRegister(*REG_FPSTATUS_TOP, st_top); } #if SEMANTIC_DOMAIN == SYMBOLIC_DOMAIN BaseSemantics::SValuePtr orig_esp; if (do_test_subst) { // Only request the orig_esp if we're going to use it later because it causes an esp value to be instantiated // in the state, which is printed in the output, and thus changes the answer. BaseSemantics::RegisterStateGeneric::promote(operators->get_state()->get_register_state())->initialize_large(); orig_esp = operators->readRegister(*regdict->lookup("esp")); std::cout <<"Original state:\n" <<*operators; } #endif /* Perform semantic analysis for each instruction in this block. The block ends when we no longer know the value of * the instruction pointer or the instruction pointer refers to an instruction that doesn't exist or which has already * been processed. */ while (1) { /* Analyze current instruction */ std::cout <<"\n" <<unparseInstructionWithAddress(insn) <<"\n"; try { dispatcher->processInstruction(insn); # if 0 /*DEBUGGING [Robb P. Matzke 2013-05-01]*/ show_state(operators); // for comparing RegisterStateGeneric with the old RegisterStateX86 output # else std::cout <<(*operators + formatter); # endif } catch (const BaseSemantics::Exception &e) { std::cout <<e <<"\n"; } /* Never follow CALL instructions */ if (insn->get_kind()==x86_call || insn->get_kind()==x86_farcall) break; /* Get next instruction of this block */ BaseSemantics::SValuePtr ip = operators->readRegister(dispatcher->findRegister("eip")); if (!ip->is_number()) break; rose_addr_t next_addr = ip->get_number(); si = insns.find(next_addr); if (si==insns.end()) break; insn = si->second; insns.erase(si); } // Test substitution on the symbolic state. #if SEMANTIC_DOMAIN == SYMBOLIC_DOMAIN if (do_test_subst) { SymbolicSemantics::SValuePtr from = SymbolicSemantics::SValue::promote(orig_esp); BaseSemantics::SValuePtr newvar = operators->undefined_(32); newvar->set_comment("frame_pointer"); SymbolicSemantics::SValuePtr to = SymbolicSemantics::SValue::promote(operators->add(newvar, operators->number_(32, 4))); std::cout <<"Substituting from " <<*from <<" to " <<*to <<"\n"; SymbolicSemantics::RiscOperators::promote(operators)->substitute(from, to); std::cout <<"Substituted state:\n" <<(*operators+formatter); } #endif } }
/* Analyze a single interpretation a block at a time */ static void analyze_interp(SgAsmInterpretation *interp) { /* Get the set of all instructions except instructions that are part of left-over blocks. */ struct AllInstructions: public SgSimpleProcessing, public std::map<rose_addr_t, SgAsmx86Instruction*> { void visit(SgNode *node) { SgAsmx86Instruction *insn = isSgAsmx86Instruction(node); SgAsmFunction *func = SageInterface::getEnclosingNode<SgAsmFunction>(insn); if (func && 0==(func->get_reason() & SgAsmFunction::FUNC_LEFTOVERS)) insert(std::make_pair(insn->get_address(), insn)); } } insns; insns.traverse(interp, postorder); while (!insns.empty()) { std::cout <<"=====================================================================================\n" <<"=== Starting a new basic block ===\n" <<"=====================================================================================\n"; AllInstructions::iterator si = insns.begin(); SgAsmx86Instruction *insn = si->second; insns.erase(si); #if SEMANTIC_API == NEW_API BaseSemantics::RiscOperatorsPtr operators = make_ops(); BaseSemantics::Formatter formatter; formatter.set_suppress_initial_values(); BaseSemantics::DispatcherPtr dispatcher; if (do_trace) { TraceSemantics::RiscOperatorsPtr trace = TraceSemantics::RiscOperators::instance(operators); trace->set_stream(stdout); dispatcher = DispatcherX86::instance(trace); } else { dispatcher = DispatcherX86::instance(operators); } operators->set_solver(make_solver()); #else // OLD_API typedef X86InstructionSemantics<MyPolicy, MyValueType> MyDispatcher; MyPolicy operators; MyDispatcher dispatcher(operators); # if SEMANTIC_DOMAIN == SYMBOLIC_DOMAIN operators.set_solver(make_solver()); SymbolicSemantics::Formatter formatter; formatter.expr_formatter.do_rename = true; formatter.expr_formatter.add_renames = true; # elif SEMANTIC_DOMAIN != FINDCONST_DOMAIN && SEMANTIC_DOMAIN != FINDCONSTABI_DOMAIN BaseSemantics::Formatter formatter; # endif #endif #if SEMANTIC_DOMAIN == SYMBOLIC_DOMAIN && SEMANTIC_API == NEW_API BaseSemantics::SValuePtr orig_esp; if (do_test_subst) { // Only request the orig_esp if we're going to use it later because it causes an esp value to be instantiated // in the state, which is printed in the output, and thus changes the answer. BaseSemantics::RegisterStateGeneric::promote(operators->get_state()->get_register_state())->initialize_large(); orig_esp = operators->readRegister(*regdict->lookup("esp")); std::cout <<"Original state:\n" <<*operators; } #endif /* Perform semantic analysis for each instruction in this block. The block ends when we no longer know the value of * the instruction pointer or the instruction pointer refers to an instruction that doesn't exist or which has already * been processed. */ while (1) { /* Analyze current instruction */ std::cout <<"\n" <<unparseInstructionWithAddress(insn) <<"\n"; #if SEMANTIC_API == NEW_API try { dispatcher->processInstruction(insn); # if 0 /*DEBUGGING [Robb P. Matzke 2013-05-01]*/ show_state(operators); // for comparing RegisterStateGeneric with the old RegisterStateX86 output # else std::cout <<(*operators + formatter); # endif } catch (const BaseSemantics::Exception &e) { std::cout <<e <<"\n"; } #else // OLD API try { dispatcher.processInstruction(insn); # if SEMANTIC_DOMAIN == FINDCONST_DOMAIN || SEMANTIC_DOMAIN == FINDCONSTABI_DOMAIN operators.print(std::cout); # else operators.print(std::cout, formatter); # endif } catch (const MyDispatcher::Exception &e) { std::cout <<e <<"\n"; break; # if SEMANTIC_DOMAIN == PARTSYM_DOMAIN } catch (const MyPolicy::Exception &e) { std::cout <<e <<"\n"; break; # endif } catch (const SMTSolver::Exception &e) { std::cout <<e <<" [ "<<unparseInstructionWithAddress(insn) <<"]\n"; break; } #endif /* Never follow CALL instructions */ if (insn->get_kind()==x86_call || insn->get_kind()==x86_farcall) break; /* Get next instruction of this block */ #if SEMANTIC_API == NEW_API BaseSemantics::SValuePtr ip = operators->readRegister(dispatcher->findRegister("eip")); if (!ip->is_number()) break; rose_addr_t next_addr = ip->get_number(); #else // OLD_API # if SEMANTIC_DOMAIN == PARTSYM_DOMAIN || SEMANTIC_DOMAIN == SYMBOLIC_DOMAIN MyValueType<32> ip = operators.get_ip(); if (!ip.is_known()) break; rose_addr_t next_addr = ip.known_value(); # elif SEMANTIC_DOMAIN == NULL_DOMAIN || SEMANTIC_DOMAIN == INTERVAL_DOMAIN MyValueType<32> ip = operators.readRegister<32>(dispatcher.REG_EIP); if (!ip.is_known()) break; rose_addr_t next_addr = ip.known_value(); # elif SEMANTIC_DOMAIN == MULTI_DOMAIN PartialSymbolicSemantics::ValueType<32> ip = operators.readRegister<32>(dispatcher.REG_EIP) .get_subvalue(MyMultiSemanticsClass::SP0()); if (!ip.is_known()) break; rose_addr_t next_addr = ip.known_value(); # else if (operators.newIp->get().name) break; rose_addr_t next_addr = operators.newIp->get().offset; # endif #endif si = insns.find(next_addr); if (si==insns.end()) break; insn = si->second; insns.erase(si); } // Test substitution on the symbolic state. #if SEMANTIC_DOMAIN == SYMBOLIC_DOMAIN && SEMANTIC_API == NEW_API if (do_test_subst) { SymbolicSemantics::SValuePtr from = SymbolicSemantics::SValue::promote(orig_esp); BaseSemantics::SValuePtr newvar = operators->undefined_(32); newvar->set_comment("frame_pointer"); SymbolicSemantics::SValuePtr to = SymbolicSemantics::SValue::promote(operators->add(newvar, operators->number_(32, 4))); std::cout <<"Substituting from " <<*from <<" to " <<*to <<"\n"; SymbolicSemantics::RiscOperators::promote(operators)->substitute(from, to); std::cout <<"Substituted state:\n" <<(*operators+formatter); } #endif } }