Example #1
0
 void operator()(const RegisterDescriptor &desc, const char *abbr) {
     BaseSemantics::RegisterStatePtr regstate = ops->get_state()->get_register_state();
     FormatRestorer fmt(o);
     o <<prefix <<std::setw(8) <<std::left <<abbr <<"= { ";
     fmt.restore();
     BaseSemantics::SValuePtr val = regstate->readRegister(desc, ops.get());
     o <<*val <<" }\n";
 }
std::string
NoOperation::StateNormalizer::toString(const BaseSemantics::DispatcherPtr &cpu, const BaseSemantics::StatePtr &state_) {
    BaseSemantics::StatePtr state = state_;
    BaseSemantics::RiscOperatorsPtr ops = cpu->get_operators();
    if (!state)
        return "";
    bool isCloned = false;                              // do we have our own copy of the state?

    // If possible and appropriate, remove the instruction pointer register
    const RegisterDescriptor regIp = cpu->instructionPointerRegister();
    BaseSemantics::RegisterStateGenericPtr rstate = BaseSemantics::RegisterStateGeneric::promote(state->registerState());
    if (rstate && rstate->is_partly_stored(regIp)) {
        BaseSemantics::SValuePtr ip = ops->readRegister(cpu->instructionPointerRegister());
        if (ip->is_number()) {
            state = state->clone();
            isCloned = true;
            rstate = BaseSemantics::RegisterStateGeneric::promote(state->registerState());
            rstate->erase_register(regIp, ops.get());
        }
    }

    // Get the memory state, cloning the state if not done so above.
    BaseSemantics::MemoryCellStatePtr mem =
        boost::dynamic_pointer_cast<BaseSemantics::MemoryCellState>(state->memoryState());
    if (mem && !isCloned) {
        state = state->clone();
        isCloned = true;
        mem = BaseSemantics::MemoryCellState::promote(state->memoryState());
    }

    // Erase memory that has never been written (i.e., cells that sprang into existence by reading an address) of which appears
    // to have been recently popped from the stack.
    CellErasurePredicate predicate(ops, ops->readRegister(cpu->stackPointerRegister()), ignorePoppedMemory_);
    if (mem)
        mem->eraseMatchingCells(predicate);

    BaseSemantics::Formatter fmt;
    fmt.set_show_latest_writers(false);
    fmt.set_show_properties(false);
    std::ostringstream ss;
    ss <<(*state+fmt);
    return ss.str();
}
Example #3
0
File: simulate.C Project: 8l/rose
int main(int argc, char *argv[]) {
    Diagnostics::initialize();
    ::mlog = Diagnostics::Facility("tool", Diagnostics::destination);
    Diagnostics::mfacilities.insertAndAdjust(::mlog);

    // Parse the command-line
    Partitioner2::Engine engine;
    std::vector<std::string> specimenNames = parseCommandLine(argc, argv, engine);
    if (specimenNames.empty())
        throw std::runtime_error("no specimen specified; see --help");

    // Load specimen into memory
    MemoryMap map = engine.loadSpecimens(specimenNames);

    // Configure instruction semantics
    Partitioner2::Partitioner partitioner = engine.createPartitioner();
    Disassembler *disassembler = engine.obtainDisassembler();
    const RegisterDictionary *regdict = disassembler->get_registers();
    if (disassembler->dispatcher() == NULL)
        throw std::runtime_error("no instruction semantics for this architecture");    
    BaseSemantics::RiscOperatorsPtr ops = InstructionSemantics2::ConcreteSemantics::RiscOperators::instance(regdict);
    BaseSemantics::DispatcherPtr cpu = disassembler->dispatcher()->create(ops);
    ConcreteSemantics::MemoryState::promote(ops->currentState()->memoryState())->memoryMap(map);

    // Find starting address
    rose_addr_t va = 0;
    if (settings.startVa) {
        va = *settings.startVa;
    } else if (engine.isaName() == "coldfire") {
        // Use the interrupt vector to initialize the stack pointer and instruction pointer.
        uint32_t sp, ip;
        if (4 != map.at(0).limit(4).read((uint8_t*)&sp).size())
            throw std::runtime_error("cannot read stack pointer at address 0x00000000");
        ops->writeRegister(disassembler->stackPointerRegister(), ops->number_(32, ByteOrder::be_to_host(sp)));
        if (4 != map.at(4).limit(4).read((uint8_t*)&ip).size())
            throw std::runtime_error("cannot read instruction pointer at address 0x00000004");
        va = ByteOrder::be_to_host(ip);
    } else if (!map.atOrAfter(0).require(MemoryMap::EXECUTABLE).next().assignTo(va)) {
        throw std::runtime_error("no starting address specified and none marked executable");
    }
    ops->writeRegister(disassembler->instructionPointerRegister(), ops->number_(32, va));

    // Execute
    map.dump(::mlog[INFO]);
    while (1) {
        va = ops->readRegister(disassembler->instructionPointerRegister())->get_number();
        SgAsmInstruction *insn = partitioner.instructionProvider()[va];
        SAWYER_MESG(::mlog[TRACE]) <<unparseInstructionWithAddress(insn, NULL, regdict) <<"\n";
        try {
            cpu->processInstruction(insn);
        } catch (const BaseSemantics::Exception &e) {
            ::mlog[WARN] <<e <<"\n";
        }
    }

    // std::cout <<"Final state:\n";
    // std::cout <<*ops->currentState();
}
Example #4
0
size_t
RiscOperators::add_subdomain(const BaseSemantics::RiscOperatorsPtr &subdomain, const std::string &name, bool activate)
{
    ASSERT_not_null(subdomain);
    size_t idx = subdomains.size();
    subdomains.push_back(subdomain);
    active.push_back(activate);
    if (idx>=formatter.subdomain_names.size())
        formatter.subdomain_names.resize(idx+1, "");
    formatter.subdomain_names[idx] = name;
    SValue::promote(protoval())->set_subvalue(idx, subdomain->protoval());
    return idx;
}
BaseSemantics::StatePtr
NoOperation::initialState(SgAsmInstruction *insn) const {
    ASSERT_not_null(insn);
    ASSERT_not_null(cpu_);
    BaseSemantics::StatePtr state;
    if (normalizer_) {
        state = normalizer_->initialState(cpu_, insn);
    } else {
        state = cpu_->currentState()->clone();
        state->clear();
        RegisterDescriptor IP = cpu_->instructionPointerRegister();
        state->writeRegister(IP, cpu_->number_(IP.get_nbits(), insn->get_address()), cpu_->get_operators().get());
    }

    // Set the stack pointer to a concrete value
    if (initialSp_) {
        const RegisterDescriptor regSp = cpu_->stackPointerRegister();
        BaseSemantics::RiscOperatorsPtr ops = cpu_->get_operators();
        state->writeRegister(regSp, ops->number_(regSp.get_nbits(), *initialSp_), ops.get());
    }

    return state;
}
Example #6
0
/* 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
    }
}
Example #7
0
 void operator()(const char *name, const char *abbr=NULL) {
     const RegisterDictionary *regdict = ops->get_state()->get_register_state()->get_register_dictionary();
     const RegisterDescriptor *desc = regdict->lookup(name);
     assert(desc);
     (*this)(*desc, abbr?abbr:name);
 }
Example #8
0
// Show the register state for BaseSemantics::RegisterStateGeneric in the same format as for RegisterStateX86. This is
// for comparison of the two register states when verifying results.  It's also close to the format used by the old binary
// semantics API.
void
show_state(const BaseSemantics::RiscOperatorsPtr &ops)
{
#if SEMANTIC_DOMAIN == MULTI_DOMAIN
    std::cout <<*ops;
    return;
#endif

    struct ShowReg {
        BaseSemantics::RiscOperatorsPtr ops;
        std::ostream &o;
        std::string prefix;

        ShowReg(const BaseSemantics::RiscOperatorsPtr &ops, std::ostream &o, const std::string &prefix)
            : ops(ops), o(o), prefix(prefix) {}

        void operator()(const char *name, const char *abbr=NULL) {
            const RegisterDictionary *regdict = ops->get_state()->get_register_state()->get_register_dictionary();
            const RegisterDescriptor *desc = regdict->lookup(name);
            assert(desc);
            (*this)(*desc, abbr?abbr:name);
        }
        void operator()(const RegisterDescriptor &desc, const char *abbr) {
            BaseSemantics::RegisterStatePtr regstate = ops->get_state()->get_register_state();
            FormatRestorer fmt(o);
            o <<prefix <<std::setw(8) <<std::left <<abbr <<"= { ";
            fmt.restore();
            BaseSemantics::SValuePtr val = regstate->readRegister(desc, ops.get());
            o <<*val <<" }\n";
        }
        void operator()(unsigned majr, unsigned minr, unsigned offset, unsigned nbits, const char *abbr) {
            (*this)(RegisterDescriptor(majr, minr, offset, nbits), abbr);
        }
    } show(ops, std::cout, "    ");

    std::cout <<"registers:\n";
    show("eax",         "ax");
    show("ecx",         "cx");
    show("edx",         "dx");
    show("ebx",         "bx");
    show("esp",         "sp");
    show("ebp",         "bp");
    show("esi",         "si");
    show("edi",         "di");
    show("es");
    show("cs");
    show("ss");
    show("ds");
    show("fs");
    show("gs");
    show("cf");
    show(x86_regclass_flags, 0, 1, 1, "?1");
    show("pf");
    show(x86_regclass_flags, 0, 3, 1, "?3");
    show("af");
    show(x86_regclass_flags, 0, 5, 1, "?5");
    show("zf");
    show("sf");
    show("tf");
    show("if");
    show("df");
    show("of");
    show(x86_regclass_flags, 0, 12, 1, "iopl0");
    show(x86_regclass_flags, 0, 13, 1, "iopl1");
    show("nt");
    show(x86_regclass_flags, 0, 15, 1, "?15");
    show("rf");
    show("vm");
    show(x86_regclass_flags, 0, 18, 1, "ac");
    show(x86_regclass_flags, 0, 19, 1, "vif");
    show(x86_regclass_flags, 0, 20, 1, "vip");
    show(x86_regclass_flags, 0, 21, 1, "id");
    show(x86_regclass_flags, 0, 22, 1, "?22");
    show(x86_regclass_flags, 0, 23, 1, "?23");
    show(x86_regclass_flags, 0, 24, 1, "?24");
    show(x86_regclass_flags, 0, 25, 1, "?25");
    show(x86_regclass_flags, 0, 26, 1, "?26");
    show(x86_regclass_flags, 0, 27, 1, "?27");
    show(x86_regclass_flags, 0, 28, 1, "?28");
    show(x86_regclass_flags, 0, 29, 1, "?29");
    show(x86_regclass_flags, 0, 30, 1, "?30");
    show(x86_regclass_flags, 0, 31, 1, "?31");
    show("eip", "ip");

    BaseSemantics::Formatter memfmt;
    memfmt.set_line_prefix("    ");
    std::cout <<"memory:\n";
    ops->get_state()->print_memory(std::cout, memfmt);
}
 explicit State(const BaseSemantics::RiscOperatorsPtr &ops)
     : BaseSemantics::RegisterStateGeneric(ops->get_protoval(),
                                           ops->get_state()->get_register_state()->get_register_dictionary()),
       ops_(ops) {}
Example #10
0
/* 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
    }
}
// see base class
bool
SgAsmX86Instruction::isFunctionCallSlow(const std::vector<SgAsmInstruction*>& insns, rose_addr_t *target, rose_addr_t *return_va)
{
    if (isFunctionCallFast(insns, target, return_va))
        return true;

    // The following stuff works only if we have a relatively complete AST.
    static const size_t EXECUTION_LIMIT = 10; // max size of basic blocks for expensive analyses
    if (insns.empty())
        return false;
    SgAsmX86Instruction *last = isSgAsmX86Instruction(insns.back());
    if (!last)
        return false;
    SgAsmFunction *func = SageInterface::getEnclosingNode<SgAsmFunction>(last);
    SgAsmInterpretation *interp = SageInterface::getEnclosingNode<SgAsmInterpretation>(func);

    // Slow method: Emulate the instructions and then look at the EIP and stack.  If the EIP points outside the current
    // function and the top of the stack holds an address of an instruction within the current function, then this must be a
    // function call.
    if (interp && insns.size()<=EXECUTION_LIMIT) {
        using namespace Rose::BinaryAnalysis;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2::SymbolicSemantics;
        const InstructionMap &imap = interp->get_instruction_map();
        const RegisterDictionary *regdict = RegisterDictionary::dictionary_for_isa(interp);
        SmtSolverPtr solver = SmtSolver::instance(Rose::CommandLine::genericSwitchArgs.smtSolver);
        BaseSemantics::RiscOperatorsPtr ops = RiscOperators::instance(regdict, solver);
        ASSERT_not_null(ops);
        const RegisterDescriptor SP = regdict->findLargestRegister(x86_regclass_gpr, x86_gpr_sp);
        DispatcherX86Ptr dispatcher = DispatcherX86::instance(ops, SP.get_nbits());
        SValuePtr orig_esp = SValue::promote(ops->readRegister(dispatcher->REG_anySP));
        try {
            for (size_t i=0; i<insns.size(); ++i)
                dispatcher->processInstruction(insns[i]);
        } catch (const BaseSemantics::Exception &e) {
            return false;
        }

        // If the next instruction address is concrete but does not point to a function entry point, then this is not a call.
        SValuePtr eip = SValue::promote(ops->readRegister(dispatcher->REG_anyIP));
        if (eip->is_number()) {
            rose_addr_t target_va = eip->get_number();
            SgAsmFunction *target_func = SageInterface::getEnclosingNode<SgAsmFunction>(imap.get_value_or(target_va, NULL));
            if (!target_func || target_va!=target_func->get_entry_va())
                return false;
        }

        // If nothing was pushed onto the stack, then this isn't a function call.
        const size_t spWidth = dispatcher->REG_anySP.get_nbits();
        SValuePtr esp = SValue::promote(ops->readRegister(dispatcher->REG_anySP));
        SValuePtr stack_delta = SValue::promote(ops->add(esp, ops->negate(orig_esp)));
        SValuePtr stack_delta_sign = SValue::promote(ops->extract(stack_delta, spWidth-1, spWidth));
        if (stack_delta_sign->is_number() && 0==stack_delta_sign->get_number())
            return false;

        // If the top of the stack does not contain a concrete value or the top of the stack does not point to an instruction
        // in this basic block's function, then this is not a function call.
        const size_t ipWidth = dispatcher->REG_anyIP.get_nbits();
        SValuePtr top = SValue::promote(ops->readMemory(dispatcher->REG_SS, esp, esp->undefined_(ipWidth), esp->boolean_(true)));
        if (top->is_number()) {
            rose_addr_t va = top->get_number();
            SgAsmFunction *return_func = SageInterface::getEnclosingNode<SgAsmFunction>(imap.get_value_or(va, NULL));
            if (!return_func || return_func!=func) {
                return false;
            }
        } else {
            return false;
        }

        // Since EIP might point to a function entry address and since the top of the stack contains a pointer to an
        // instruction in this function, we assume that this is a function call.
        if (target && eip->is_number())
            *target = eip->get_number();
        if (return_va && top->is_number())
            *return_va = top->get_number();
        return true;
    }

    // Similar to the above method, but works when all we have is the basic block (e.g., this case gets hit quite a bit from
    // the Partitioner).  Returns true if, after executing the basic block, the top of the stack contains the fall-through
    // address of the basic block. We depend on our caller to figure out if EIP is reasonably a function entry address.
    if (!interp && insns.size()<=EXECUTION_LIMIT) {
        using namespace Rose::BinaryAnalysis;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2::SymbolicSemantics;
        SmtSolverPtr solver = SmtSolver::instance(Rose::CommandLine::genericSwitchArgs.smtSolver);
        SgAsmX86Instruction *x86insn = isSgAsmX86Instruction(insns.front());
        ASSERT_not_null(x86insn);
#if 1 // [Robb P. Matzke 2015-03-03]: FIXME[Robb P. Matzke 2015-03-03]: not ready yet; x86-64 semantics still under construction
        if (x86insn->get_addressSize() != x86_insnsize_32)
            return false;
#endif
        const RegisterDictionary *regdict = registersForInstructionSize(x86insn->get_addressSize());
        const RegisterDescriptor SP = regdict->findLargestRegister(x86_regclass_gpr, x86_gpr_sp);
        BaseSemantics::RiscOperatorsPtr ops = RiscOperators::instance(regdict, solver);
        DispatcherX86Ptr dispatcher = DispatcherX86::instance(ops, SP.get_nbits());
        try {
            for (size_t i=0; i<insns.size(); ++i)
                dispatcher->processInstruction(insns[i]);
        } catch (const BaseSemantics::Exception &e) {
            return false;
        }

        // Look at the top of the stack
        const size_t ipWidth = dispatcher->REG_anyIP.get_nbits();
        SValuePtr top = SValue::promote(ops->readMemory(dispatcher->REG_SS, ops->readRegister(SP),
                                                        ops->protoval()->undefined_(ipWidth),
                                                        ops->protoval()->boolean_(true)));
        if (top->is_number() && top->get_number() == last->get_address()+last->get_size()) {
            if (target) {
                SValuePtr eip = SValue::promote(ops->readRegister(dispatcher->REG_anyIP));
                if (eip->is_number())
                    *target = eip->get_number();
            }
            if (return_va)
                *return_va = top->get_number();
            return true;
        }
    }

    return false;
}
Example #12
0
//! [basicReadTest]
static void
basicReadTest(const P2::Partitioner &partitioner) {
    std::cout <<"\n" <<std::string(40, '=') <<"\nbasicReadTest\n" <<std::string(40, '=') <<"\n";
    SymbolicSemantics::Formatter fmt;
    fmt.set_line_prefix("  ");

    // Create the RiscOperators and the initial state.
    const RegisterDictionary *regdict = partitioner.instructionProvider().registerDictionary();
    const RegisterDescriptor REG = partitioner.instructionProvider().stackPointerRegister();
    const std::string REG_NAME = RegisterNames(regdict)(REG);
    BaseSemantics::RiscOperatorsPtr ops = SymbolicSemantics::RiscOperators::instance(regdict);
    ops->currentState()->memoryState()->set_byteOrder(partitioner.instructionProvider().defaultByteOrder());
    BaseSemantics::StatePtr initialState = ops->currentState()->clone();
    ops->initialState(initialState);                    // lazily evaluated initial state
    std::cout <<"Initial state before reading:\n" <<(*initialState+fmt);

    // Read some memory and a register, which should cause them to spring into existence in both the current state and the
    // initial state.
    BaseSemantics::SValuePtr addr1 = ops->number_(32, 0);
    BaseSemantics::SValuePtr dflt1m = ops->number_(32, 0x11223344);
    BaseSemantics::SValuePtr read1m = ops->readMemory(RegisterDescriptor(), addr1, dflt1m, ops->boolean_(true));
    BaseSemantics::SValuePtr dflt1r = ops->undefined_(REG.get_nbits());
    BaseSemantics::SValuePtr read1r = ops->readRegister(REG, dflt1r);

    std::cout <<"Initial state after reading " <<*read1m <<" from address " <<*addr1 <<"\n"
              <<"and " <<*read1r <<" from " <<REG_NAME <<"\n"
              <<(*initialState+fmt);
    ASSERT_always_require(read1m->must_equal(dflt1m));
    ASSERT_always_require(read1r->must_equal(dflt1r));

    // Create a new current state and read again. We should get the same value even though the current state is empty.
    BaseSemantics::StatePtr curState = ops->currentState()->clone();
    curState->clear();
    ops->currentState(curState);
    BaseSemantics::SValuePtr dflt2m = ops->number_(32, 0x55667788);
    BaseSemantics::SValuePtr read2m = ops->readMemory(RegisterDescriptor(), addr1, dflt2m, ops->boolean_(true));
    BaseSemantics::SValuePtr dflt2r = ops->undefined_(REG.get_nbits());
    BaseSemantics::SValuePtr read2r = ops->readRegister(REG, dflt2r);

    std::cout <<"Initial state after reading " <<*read2m <<" from address " <<*addr1 <<"\n"
              <<"and " <<*read2r <<" from " <<REG_NAME <<"\n"
              <<(*initialState+fmt);
    ASSERT_always_require(read1m->must_equal(read2m));
    ASSERT_always_require(read1r->must_equal(read2r));

    // Disable the initial state. If we re-read the same address we'll still get the same result because it's now present in
    // the current state also.
    ops->initialState(BaseSemantics::StatePtr());
    BaseSemantics::SValuePtr dflt3m = ops->number_(32, 0x99aabbcc);
    BaseSemantics::SValuePtr read3m = ops->readMemory(RegisterDescriptor(), addr1, dflt3m, ops->boolean_(true));
    BaseSemantics::SValuePtr dflt3r = ops->undefined_(REG.get_nbits());
    BaseSemantics::SValuePtr read3r = ops->readRegister(REG, dflt3r);
    ASSERT_always_require(read1m->must_equal(read3m));
    ASSERT_always_require(read1r->must_equal(read3r));
}
Example #13
0
int
main(int argc, char *argv[]) {
    ROSE_INITIALIZE;
    Diagnostics::initAndRegister(&::mlog, "tool");
    parseCommandLine(argc, argv);

    // Create the machine state
    const RegisterDictionary *registers = RegisterDictionary::dictionary_amd64();
    const RegisterDescriptor EAX = *registers->lookup("eax");
    SmtSolverPtr solver;
    BaseSemantics::RiscOperatorsPtr ops = SymbolicSemantics::RiscOperators::instance(registers, solver);
    ops->currentState()->memoryState()->set_byteOrder(ByteOrder::ORDER_LSB);

    // Initialize the machine state with some writes and get the string representation.
    BaseSemantics::SValuePtr eax = ops->number_(32, 1234);
    ops->writeRegister(EAX, eax);
    BaseSemantics::SValuePtr addr0 = ops->number_(32, 0x1000);
    BaseSemantics::SValuePtr mem0 = ops->number_(8, 123);
    ops->writeMemory(RegisterDescriptor(), addr0, mem0, ops->boolean_(true));
    std::ostringstream s0;
    s0 <<*ops;
    
    // Peek at parts of the state that exist
    BaseSemantics::SValuePtr v1 = ops->peekRegister(EAX, ops->undefined_(32));
    ASSERT_always_not_null(v1);
    ASSERT_always_require(v1->must_equal(eax, solver));
    BaseSemantics::SValuePtr mem1 = ops->peekMemory(RegisterDescriptor(), addr0, ops->undefined_(8));
    ASSERT_always_not_null(mem1);
    ASSERT_always_require(mem1->must_equal(mem0, solver));
    std::ostringstream s1;
    s1 <<*ops;
    ASSERT_always_require2(s0.str() == s1.str(), s1.str());

    // Peek at parts of the state that don't exist
    const RegisterDescriptor EBX = *registers->lookup("ebx");
    BaseSemantics::SValuePtr ebx = ops->undefined_(32);
    BaseSemantics::SValuePtr v2 = ops->peekRegister(EBX, ebx);
    ASSERT_always_not_null(v2);
    ASSERT_always_require(v2->must_equal(ebx, solver));
    BaseSemantics::SValuePtr addr2 = ops->number_(32, 0x2000);
    BaseSemantics::SValuePtr mem2init = ops->undefined_(8);
    BaseSemantics::SValuePtr mem2 = ops->peekMemory(RegisterDescriptor(), addr2, mem2init);
    ASSERT_always_not_null(mem2);
    ASSERT_always_require(mem2->must_equal(mem2init, solver));
    std::ostringstream s2;
    s2 <<*ops;
    ASSERT_always_require2(s0.str() == s2.str(), s2.str());

    // Peek at parts of the state that partly exist.
    const RegisterDescriptor RAX = *registers->lookup("rax");
    BaseSemantics::SValuePtr zero64 = ops->number_(64, 0);
    BaseSemantics::SValuePtr v3 = ops->peekRegister(RAX, zero64);
    ASSERT_always_not_null(v3);
    ASSERT_always_require(v3->must_equal(ops->number_(64, 1234), solver));
    BaseSemantics::SValuePtr zero32 = ops->number_(32, 0);
    BaseSemantics::SValuePtr mem3ans = ops->number_(32, 123);
    BaseSemantics::SValuePtr mem3 = ops->peekMemory(RegisterDescriptor(), addr0, zero32);
    ASSERT_always_not_null(mem3);
    ASSERT_always_require(mem3->must_equal(mem3ans, solver));
    std::ostringstream s3;
    s3 <<*ops;
    ASSERT_always_require2(s0.str() == s3.str(), s3.str());

    std::cout <<s3.str();
}
// see base class; don't modify target_va or return_va if they are not known
bool
SgAsmM68kInstruction::isFunctionCallSlow(const std::vector<SgAsmInstruction*>& insns, rose_addr_t *target_va,
                                         rose_addr_t *return_va)
{
    if (isFunctionCallFast(insns, target_va, return_va))
        return true;

    static const size_t EXECUTION_LIMIT = 25; // max size of basic blocks for expensive analyses
    if (insns.empty())
        return false;
    SgAsmM68kInstruction *last = isSgAsmM68kInstruction(insns.back());
    if (!last)
        return false;
    SgAsmFunction *func = SageInterface::getEnclosingNode<SgAsmFunction>(last);
    SgAsmInterpretation *interp = SageInterface::getEnclosingNode<SgAsmInterpretation>(func);

    // Slow method: Emulate the instructions and then look at the program counter (PC) and stack (A7).  If the PC points
    // outside the current function and the top of the stack holds an address of an instruction within the current function,
    // then this must be a function call.
    if (interp && insns.size()<=EXECUTION_LIMIT) {
        using namespace Rose::BinaryAnalysis;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2::SymbolicSemantics;
        const InstructionMap &imap = interp->get_instruction_map();
        const RegisterDictionary *regdict = RegisterDictionary::dictionary_for_isa(interp);
        SmtSolverPtr solver = SmtSolver::instance(Rose::CommandLine::genericSwitchArgs.smtSolver);
        BaseSemantics::RiscOperatorsPtr ops = RiscOperators::instance(regdict, solver);
        DispatcherM68kPtr dispatcher = DispatcherM68k::instance(ops, 32);
        SValuePtr orig_sp = SValue::promote(ops->readRegister(dispatcher->REG_A[7]));
        try {
            for (size_t i=0; i<insns.size(); ++i)
                dispatcher->processInstruction(insns[i]);
        } catch (const BaseSemantics::Exception &e) {
            return false;
        }

        // If the next instruction address is concrete but does not point to a function entry point, then this is not a call.
        SValuePtr ip = SValue::promote(ops->readRegister(dispatcher->REG_PC));
        if (ip->is_number()) {
            rose_addr_t target_va = ip->get_number();
            SgAsmFunction *target_func = SageInterface::getEnclosingNode<SgAsmFunction>(imap.get_value_or(target_va, NULL));
            if (!target_func || target_va!=target_func->get_entry_va())
                return false;
        }

        // If nothing was pushed onto the stack, then this isn't a function call.
        SValuePtr sp = SValue::promote(ops->readRegister(dispatcher->REG_A[7]));
        SValuePtr stack_delta = SValue::promote(ops->add(sp, ops->negate(orig_sp)));
        SValuePtr stack_delta_sign = SValue::promote(ops->extract(stack_delta, 31, 32));
        if (stack_delta_sign->is_number() && 0==stack_delta_sign->get_number())
            return false;

        // If the top of the stack does not contain a concrete value or the top of the stack does not point to an instruction
        // in this basic block's function, then this is not a function call.
        SValuePtr top = SValue::promote(ops->readMemory(RegisterDescriptor(), sp, sp->undefined_(32), sp->boolean_(true)));
        if (top->is_number()) {
            rose_addr_t va = top->get_number();
            SgAsmFunction *return_func = SageInterface::getEnclosingNode<SgAsmFunction>(imap.get_value_or(va, NULL));
            if (!return_func || return_func!=func) {
                return false;
            }
        } else {
            return false;
        }

        // Since the instruction pointer might point to a function entry address and since the top of the stack contains a
        // pointer to an instruction in this function, we assume that this is a function call.
        if (target_va && ip->is_number())
            *target_va = ip->get_number();
        if (return_va && top->is_number())
            *return_va = top->get_number();
        return true;
    }

    // Similar to the above method, but works when all we have is the basic block (e.g., this case gets hit quite a bit from
    // the Partitioner).  Returns true if, after executing the basic block, the top of the stack contains the fall-through
    // address of the basic block. We depend on our caller to figure out if the instruction pointer is reasonably a function
    // entry address.
    if (!interp && insns.size()<=EXECUTION_LIMIT) {
        using namespace Rose::BinaryAnalysis;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2;
        using namespace Rose::BinaryAnalysis::InstructionSemantics2::SymbolicSemantics;
        const RegisterDictionary *regdict = RegisterDictionary::dictionary_coldfire_emac();
        SmtSolverPtr solver = SmtSolver::instance(Rose::CommandLine::genericSwitchArgs.smtSolver);
        BaseSemantics::RiscOperatorsPtr ops = RiscOperators::instance(regdict, solver);
        DispatcherM68kPtr dispatcher = DispatcherM68k::instance(ops, 32);
        try {
            for (size_t i=0; i<insns.size(); ++i)
                dispatcher->processInstruction(insns[i]);
        } catch (const BaseSemantics::Exception &e) {
            return false;
        }

        // Look at the top of the stack
        SValuePtr top = SValue::promote(ops->readMemory(RegisterDescriptor(), ops->readRegister(dispatcher->REG_A[7]),
                                                        ops->protoval()->undefined_(32),
                                                        ops->protoval()->boolean_(true)));
        if (top->is_number() && top->get_number() == last->get_address()+last->get_size()) {
            if (target_va) {
                SValuePtr ip = SValue::promote(ops->readRegister(dispatcher->REG_PC));
                if (ip->is_number())
                    *target_va = ip->get_number();
            }
            if (return_va)
                *return_va = top->get_number();
            return true;
        }
    }

    return false;
}